Genealogy Data Communication

Genealogy Data Communication

Genealogy Data Communication or GEDCOM is a specification which is used to exchange information between different genealogy software. It is a plain text file of the '.ged' format used for sharing genealogical information of individuals and meta data linking their information records.

The GEDCOM formats are supported by most of the genealogy software available and in use today. This format was developed by the Family History Department of The Church of Jesus Christ of the Latter-Day Saints as a support system for the genealogical research. This file can be read in editors like Notepad or Textpad and hence allows various types of computers and programs to share genealogical data. Its format and usage are described in a written and open specification. The format was readily adopted by different vendors in a variety of software products and has become a standard for genealogy programs. Genealogists, the world over use GEDCOM to save,transfer and edit files containing genealogical data.

The Concept
GEDCOM structure is the collection of data based on a nuclear family and the concerned individual name. It is neither a verification model nor goes deep into research for the 'original' form, if it exists. This format simply allows the structuring of data in accordance with the records of the family and individuals as entered in the storage. Each GEDCOM file contains a header, trailer and a record section. The records section comprises certain notes and the data specification as IND for individual or FAM for family record and so on. Much like an excel sheet, every GEDCOM file contains the top level of the main top-level records like IND, FAM or NOTE. The other level numbers are positive integers incorporating further information on the subject.

It is simply a database of records wherein the pointers track the location of the relation and the individual concerned. For example, a name 'Sara Parker' would be enlisted or found in the file sharing database of the 'Parker' family tree and can be traced with reference to the searched genealogical base. Thus, there are two sections of a GEDCOM file. The first section includes the name and information of an individual. The second section lists all the associated relationships of that individual.

Working with GEDCOM files
Although, a GEDCOM file can be read by any text editor, it is always preferable to use a software application that is specially designed for viewing tree diagrams or GEDCOM formats. The first and foremost step on downloading or on receiving a GEDCOM file through an e-mail account, is to save it in a safe and easy to locate place on the hard drive. Ensure the authenticity of the genealogy file. As stated earlier, the format or the file extension is '.ged'; although, a compressed GEDCOM file uses a '.zip' extension. A file created in a tree diagram format by a random genealogy software program is not the recommended format to be used. Last but not the least, the file has to be decompressed, if at all it is in a zip file and then opened with the existing GEDCOM format. The file systems used in GEDCOM's lately, allow a great deal of flexibility in its usage. Multimedia files capturing your precious events like a marriage or birthday parties can also be stored in this format. The latest version in development is the GEDCOM 6.0, also known as GEDCOM XML.

Until now, the GEDCOM files were limited to the desktops of the genealogists. A new concept called the GenWeb, which means GEDCOM on the Internet allows instant access to a database of any family tree and all the associated services. GEDCOM files save as much as 80% storage space as compared to a '.txt' file format. An usual family tree format with all the graphic features saves a data of 2000 family members in a 6MB file, a GEDCOM format stores the same in 450 K bytes file. Future genealogy programs will integrate reasoning and require proof along with the entry in a database. For example, any significant event will have to be supported with corresponding evidences or reasoning to validate its authenticity.

Let us hope that with GEDCOM, the information becomes more detailed and as trustworthy as possible.
By Prashant Magar

Human Cloning

Human Cloning

What is Human Cloning?
Cloning an organism involves replicating the DNA of that organism in a new organism that, as a result, has the same exact features and characteristics. Human Cloning would mean recreating the person that is being cloned. With the successful cloning of Dolly The Sheep, Human Cloning, long the staple of science fiction, is on the verge of becoming a reality.

How would Human Cloning work?
Human Cloning, if it is ever done, will be carried out by the same method that brought forth Dolly, Reproductive Cloning.

In Reproductive Cloning, the nucleus is removed from a body cell of the organism to be cloned and this nucleus is inserted into an enucleated egg, that is, an egg whose nucleus has previously been removed.

The egg with the new nucleus is then treated to electric or chemical treatment to simulate cell division. The resulting embryo is transferred to a host uterus to develop properly and eventually be given birth to.

The new-born organism will be a replica of the original organism, but not the exact same actually, since it will have DNA derived from both the organism as well as the egg.

Why would Human Cloning be done?
Cloning animals, especially endangered species, is one way of preserving the species from dying out entirely. But why would anyone want to clone human beings? There are enough of us already on the planet without resources enough for the well-being of all of us. So why bother to clone?

Well, one reason is pure scientific research. We've already come a long way. After Dolly, scientists have managed to clone various animals. So cloning humans seems the next logical step and a very important one it would be too.

Cloning humans could also prove a major breakthrough as far as cloning for therapeutic purposes is concerned. Cloning could be used to produce new organs for organ transplants. Since the cloned organ, produced from a body cell of the person needing the transplant, would have the same genetic code, there would be less risk of the body rejecting the new, transplanted organ. Cloning could also be used to treat Cancer, Alzheimer's and Parkinson's Diseases, and host of other illnesses.

Cloning would allow infertile couples to have their own genetic offspring or otherwise normal couples to order designer babies. It could also be used to bring back to life your dead ancestors. So if you want to give birth to your great-great-grandmother, you can. Just as long you managed to preserve some samples of her body cells.

One American couple reportedly is willing to pay $500,000 to clone their dead infant daughter.

And then there are some who would like to clone themselves and thereby achieve eternal life.

Is it ethical to go ahead and clone humans?
Well, sometimes one of a kind is more than one can tolerate. But, on the serious side, many of the leading Scientists involved in cloning research, like Ian Wilmut and Richard Gardner, have expressed serious doubts and ethical dilemmas over the cloning of human beings.

Firstly, reproductive cloning is not yet a fool-proof method. It took 272 attempts before Dolly was produced. This means 272 embryos either failed to develop properly or were discarded as defective. In other cases, if the embryos weren't miscarried, a large percentage of the animals born showed a high degree of abnormality and died quickly or had to be euthanized. Those successfully cloned have showed many health problems and none have lived to a ripe old age so far.

Now, since human beings consider themselves a class apart, obviously many moral problems would arise with treating defective human embryos or new-born, handicapped babies in the very same manner.

There is also no way of predicting what the intelligence level and capabilities of a human clone would be. What would be the psychological and societal implications for it as an individual? What kind of a life or future would it have? Since we don't know, many people consider it unethical to go ahead and clone.

But that argument doesn't hold much water with others. After all, we have no way of knowing exactly what sort of a person a normally conceived embryo will turn out to be either.

Is Human Cloning legally allowed?
Reproductive Cloning of Humans is banned is many countries around the world, including the USA and the UK, and allowed in some. Therapeutic Cloning is allowed to some degree, but there is already a clamor against it from religious and pro-life organizations, many of whom are more acquainted with its theological implications than its theoretical possibilities.

What is Human Gene Therapy

What is Human Gene Therapy

Human gene therapy is a milestone in the field of medical science, applicable for treatment of chronic health conditions and genetic disorders. However, there are certain factors related to the effectiveness of gene therapy techniques such as autoimmune responses, vectors, multigene disorders...

A gene is a stretch of DNA (deoxyribonucleic acid) that contains nucleotide sequences. Based on the nucleotide sequences, specific proteins are synthesized, which in turn, are responsible for expression and function of body cells and tissues. If there is any alteration in the genetic sequence, the protein synthesis is disturbed. In such a condition, the cells and tissues are unable to perform their normal function, leading to genetic diseases.

What is Human Gene Therapy

Human gene therapy is a scientific technique, by which a segment of nucleotide sequence or gene is inserted into an individual's cell for the purpose of treating diseases. The main principle behind gene therapy is to restore the normal functioning of cells and tissues by replacing abnormal or mutated genes. In simple terms, it is a method of correcting defective genes. There are several ways of implementing gene therapy; inserting a normal gene in the genome to replace a defective gene and changing the regulation for expression of a specific gene. Another method of gene therapy is to apply selective reverse mutation so that the defective gene returns to its original form.

In majority of human gene therapy cases, a normal therapeutic gene is inserted by using a vector or a carrier molecule. As the name suggests, the vector serves the purpose of delivering the normal gene to the target cell. As the vector incorporates the therapeutic gene in the target cell (for example liver cells), the therapeutic gene starts producing functional proteins, thus restoring the normal function of the target cell. While speaking about the vector or carrier molecule, various types of viruses such as retrovirus and adenovirus are used for the purpose. Before using any of these viruses as vectors, the genomic content is changed by removing disease-causing gene and replacing it with therapeutic gene.

Pros and Cons of Human Gene Therapy

There are many potential side effects of using viruses as vectors, some of which include target-related problems, inflammatory response of the immune system and at times, toxicity. A more recent technique of human gene therapy is to introduce the normal gene directly to the target cell without using vectors. Though this method sounds comparatively easy, it is not applicable to all types of target cells. Another disadvantage of this method is that it requires large amount of DNA.

A major drawback of gene therapy is the short-term effectiveness of the therapeutic gene after introducing into the target cell. It is the dividing cells present in the body that prevents the expression of therapeutic genes. After inserting the foreign therapeutic gene into the target cell, it is necessary to regulate the autoimmune responses of the body. Human gene therapy is less effective for multigene problems (presence of many defective genes).

Though the technology of human gene therapy is not so advanced in the present scenario, it has already widened the scope of medical science. As all genetic disorders and most of the chronic diseases involve malfunctioning of the genes, gene therapy is a promising technique for treatment of such severe health conditions. Genetic researches based on human gene therapy are ongoing to discover treatment options for chronic medical conditions such as heart disease, cancer, cystic fibrosis and AIDS. Nowadays, private grants as well as government grants are provided so as to encourage studies on human gene therapy.

Polygenic Traits

Polygenic Traits

Polygenic traits are different physical characteristics of individuals, due to specific inheritance patterns. It is responsible for difference in phenotypic makeup of individuals. Physical appearance of individuals is determined by genotypic ratio and chromosomal inheritance. This phenomenon was put forth by Mendel, popularly known as 'Mendel's Laws of Inheritance'. In case of polygenic traits, the characteristic features of individual result from interaction of different genes. In layman's language, we can exemplify with an individual having high blood pressure. High blood pressure does not result due to activity of single gene. This particular phenotype is the net result of interaction of cholesterol genes, obesity genes, transporter genes and addictive genes. The combined effect of these multiple genes or polygenes, is the reason behind high blood pressure. That was an elementary approach of polygenic traits. You might also like to read more on interesting aspects of human genetics.

Genetic Phenomenon of Polygenic Traits

Polygenic traits is not only observed in human beings but are also present in animals, birds, insects, flies etc. In terms of human genetics, polygenic traits is defined as, inherited characteristics when two or more genes are involved in determining the phenotype of individuals. Thus, the cumulative effects of genes are responsible for determining many traits like, weight, height, shape, color and metabolic rate of individuals. They characteristics of polygenic traits are:

    Polygenic traits do not follow Mendel's patterns of inheritance.
    They are recognized by their expressions that result from gradation of continuous variation.
    Additive effects of two or more separate pair of genes control continuous variation.
    The traits are quantified by measuring the variation, rather than counting.
    The phenotypic expression vary in wider range as a result of contributing pairs of genes.

Polygenic traits are also known as quantitative traits or multifactorial traits. To understand these synonyms, you need to understand the mechanism of genetic inheritance. Polygenic traits are controlled by two or more genes at different loci on different chromosomes or it is the trait that is controlled by non-allelic genes. They are known as quantitative traits as their phenotypic expression is dependent on multiple alleles located on different chromosomes. You might also like to read about genetic drift.

The quantitative aspect (e.g how tall or how short) or phenotype of the individual is represented as trait value. When frequency of individuals with polygenic traits is plotted against trait value, the graph is bell shaped. Polygenic traits are result of additive effects of contribution of each genes in loci and therefore they do not follow typical dominance and recessive patterns. The second aspect of polygenic genes are, the traits are determined by environmental variations. It means that an individual can be genetically same, but can differ in their physical appearance, while rest are congenial disorders. Polygenic traits can be determined by knowing the number of quantitative trait loci, that plays an important role in determining the genetic architecture of an individual. Read more on genetic disorders in humans.

Examples of Polygenic Traits in Humans

Examples of polygenic traits, governed by environmental factors are:

    Weight
    Height
    Eye color
    Intelligence
    Behavior
    Skin color

Polygenic traits examples with disorders in genetic components are:

    Cleft palate
    Cancer
    Diabetes
    Autism
    Congenital heart disease
    Congenital dislocation of hip
    Talipes
    Pyloric stenosis
    Neural tube defects
    Schizophrenia
    Diabetes Mellitus
    Glaucoma
    Hypertension
    Manic depression
    Ischaemic heart disease
    Maniac depression
    Eczema
    Dermatitis
    Spina bifida
    Anencephaly

Read more on:

    Understanding Genes
    Facts about Human Chromosomes

Polygenic traits is an important genetic phenomenon, governing different variations and characteristic in individuals. Polygenic traits in humans are interesting to study and observe.

NOTE
Glossary of Terms

    Genes: Unit of heredity in a living organism.
    Chromosomes: Organized structure of DNA and protein that embeds genes.
    Alleles: Different forms of genes in a single genetic locus.
    Genetic Locus: Specific location of gene or DNA sequence in chromosome.
    Phenotype: Observable characteristics, morphology, physiological properties of an organism
    Genotype: Information in genes that determines the phenotypic traits.
    Quantitative Trait Locus (QTL): Region of DNA, found in different chromosomes, associated with a particular phenotypic trait.
 

Facts about Human Chromosomes

Facts about Human Chromosomes

Human chromosomes are strands of DNA carrying all the important information about the human being. To look at some interesting facts about the human chromosomes,

A chromosome, by definition, is a threadlike strand of DNA in a cell nucleus that carries genes, the units of heredity in a linear order. Human beings have 22 chromosome pairs and a pair of sex chromosomes. Apart from genes, the chromosomes also contain regulatory elements and nucleotide sequences. They house the DNA-bound proteins, which control the functions of the DNA. Interestingly, the word chromosome originated from the Greek word, 'chrome' meaning color. Chromosomes got their name owing to their property of being stained by dyes. The structure and nature of chromosomes varies across different kinds of organisms. Human chromosomes have always been a subject of interest for the researchers working in genetics. The wide range of factors that human chromosomes determine, the abnormalities they are responsible for and their complex nature have always invited interest of many. Let us look at some interesting facts about the human chromosomes.

Facts about Human Chromosomes
Human cells have 23 pairs of nuclear chromosomes. A chromosome is made up of a DNA molecule that contains genes. A chromosomal DNA molecule contains three nucleotide sequences, which are required for replication. On staining the chromosomes, the banded structure of the mitotic chromosomes becomes apparent. Each band contains numerous DNA nucleotide pairs.

Human beings are sexually reproducing species and have diploid somatic cells having two sets of chromosomes. One set is inherited from the mother while the other one from the father. As against the body cells, the reproductive cells have a single set of chromosomes. The crossover between chromosomes results in the creation of new chromosomes. The newly created chromosomes are not inherited from any single parent. This brings about the fact that not all of us exhibit traits that are directly derived from one of our parents!

There are 24 distinct human chromosomes out of which 22 are autosomal chromosomes and the remaining two are sex-determining chromosomes. The autosomal human chromosomes are numbered from 1 to 22 in the decreasing order of their size. Every individual has two sets of the 22 chromosomes, X chromosome from the mother and an X or a Y chromosome from the father.

An abnormality in the content of the chromosomes of a cell can cause certain genetic disorders in human beings. Chromosomal abnormalities in human beings are often responsible for the appearance of the genetic disorder in their children. Those with chromosomal abnormalities are often only the carriers of the disorder while their children actually exhibit the disorders.

Chromosomal aberrations are caused by a variety of factors namely, deletion or duplication of a part of a chromosome, the inversion, which is the reversal of direction of a chromosome or a translocation wherein a part of a chromosome breaks off to attach to some other chromosome.

An extra copy of chromosome 21 is responsible for the very well-known genetic disorder that is known as the Down's syndrome. The trisomy of chromosome 18 results in the Edwards syndrome that may cause death in infancy.

The deletion of a part of the fifth chromosome leads to a genetic disorder known as 'cri du chat', meaning 'cry of a cat'. The human beings affected by this disorder show a cat-like crying in childhood and are often mentally retarded.

The disorders caused by sex chromosomes include the Turner syndrome wherein female sexual characteristics are present but underdeveloped, the Triple-X syndrome in girls and the XXY syndrome in boys, both causing dyslexia in the affected individuals.

Chromosomes were first discovered in plants. Van Beneden's monograph on the fertilized eggs of a roundworm, led the research further. Later in time, August Weismann proclaimed that the germ line was different from the soma and he discovered that the cell nucleus housed the hereditary material. He also proposed that fertilization results in a new combination of chromosomes.

These discoveries were cornerstones in the field of genetics. Researchers have achieved a sufficient amount of knowledge of human chromosomes and genes but there is still a lot to be discovered.

Interesting Aspects of Human Genetics

Interesting Aspects of Human Genetics

Human genetics revolves around the influence of genes on human nature and behavior patterns. It is associated with certain personality traits as well as disorders in human beings. Let us look at the interesting aspects of human genetics.

The fact that human genetics can answer questions related to diseases in human beings, their treatment, the genetic disorders and more importantly the human nature, makes this field interesting. It includes different fields such as classical and clinical genetics and genomics. Human genetics deals with the study of the inheritance pattern in the human beings. The potential uses of human genetics in the study of human nature and its prospective applications in medicine have made it a subject of interest for one and all.

Interesting Aspects of Human Genetics

Gregor Mendel studied the inheritance of the traits in living beings. He concluded that inheritance depends upon discrete units known as genes and he came up with a model of inheritance. He deduced that the inheritance of traits follows certain laws. For his significant work in genetics, Mendel is known as the father of genetics.

Inheritance traits in human beings are either autosomal or X or Y linked. Autosomes are the non-sex chromosomes whereas the X-linked and the Y-linked genes are found on the sex chromosomes. Let us look at each of them.

    In case of autosomal recessive inheritance, a trait or a disorder is passed on through families. For a recessive trait to show in humans, two copies of that trait are required. Since two copies of the disorder or the trait are needed for its display, it can remain hidden for generations together. Many human beings can be unaware of the fact that they are acting as carriers of the trait or disorder.
    Autosomal dominant inheritance is a pattern wherein a single copy of a trait is sufficient for it to appear in a human being. If one of the parents has this trait, it can be displayed in their children.
    Traits inherited from the sex chromosomes include the X-linked and the Y-linked inheritance. X-linked genes can be autosomal or recessive. Recessive X-linked disorders are common among males. As a father passes his Y chromosome to his son, X-linked traits or disorders are inherited from the maternal side. The expression of X-linked traits in the females depends on their zygosity for the trait. When a female is homozygous for a particular trait or disorder, it means that she carries two identical copies of the gene affecting that trait. In case she is heterozygous for a particular disorder, it means that she has two different alleles for that disorder. Homozygous females display X-linked disorders while the heterozygous females become carriers for the disorder. Y-linked disorders are carried on the Y chromosome. As it is present only in males, a Y-linked trait is transferred from a father to his son.

Apart from the nuclear DNA, human beings possess mitochondrial DNA. It is believed that the mitochondria are descended from a proteobacterium, which merged with eukaryotic cells, around two billion years ago. Mitochondrial DNA is about 16 KB long. A human being inherits mitochondria from his/her mother. This makes it evident that DNA can be used to track a person's maternal lines. Interestingly, in some species like the mussels or insects like the honeybees, paternally inherited mitochondria are observed. A single case of paternal inheritance of mitochondria was reported in humans. But it was associated with infertility.

Genes play a vital role in personality characteristics and human behavior. Facial features are linked to genetic constitution of an individual. A human being inherits the characteristics like facial dimples, color of the iris, the structure of the earlobe and other such traits through the genes. Attributes such as the overall stature and susceptibility to certain diseases are also inherited genetically.

Human genetics has evolved to a level where we have been able to manipulate the genetic constitution of an embryo to a certain extent through genetic engineering. The knowledge of human genetics has led us to be able to enhance the positive traits in humans while removing the negative ones. The various interesting aspects of human genetics have unfolded the mysteries of the physical and psychological characteristics of humans and opened doors to the betterment of human life.

DNA Transcription

DNA Transcription

Deoxyribonucleic acid, in short DNA, is the genetic material of all living organisms (except in some prokaryotes). The main function of DNA is to store genetic information, responsible for the construction and development of all cells. A stretch of DNA is called a gene and many genes makeup a structure called chromosome. Genes contain the hereditary information of an individual and are responsible for the phenotypic (physical or external) characters and genotypic make-up. Genetic diseases are caused due to passing of certain abnormal genes from the parents to the offspring. A specific set of chromosomes are present in a living organism, for example, human chromosomes are 46 in number.

DNA is a nucleic acid, consisting of two strands of polynucleotides. In a DNA structure, the two nucleotide strands are arranged in an anti-parallel manner, in which they run in opposite directions. The nucleotides are made up of base molecules, sugar molecules and phosphate groups. The sugars and phosphates are joined by phosphodiester bonds and in each of the sugar molecules, a base molecule is attached. DNA present in the nucleus of a cell is called nDNA or simply DNA; whereas, DNA located in the mitochondria of a cell is referred to as mitochondrial DNA or mtDNA. Let's take a look at eukaryotic DNA transcription for expression of genes.

DNA Transcription: A Brief Explanation

While controlling cellular activity, DNA undergoes coding for synthesis of enzymes and proteins. In the process of protein synthesis, the DNA molecules are not converted directly to proteins, but they are transcribed first as mRNA (messenger RNA), which is then translated to proteins. In genetics, the whole process of converting DNA to mRNA to protein is known as central dogma. The first step of transcribing DNA nucleotide to mRNA is known as DNA transcription. Let's discuss in brief about the transcription of nDNA.

In DNA transcription, specific enzymes called RNA polymerases and other proteins play a major role. There are specific nucleotide sequences in the DNA strand, which act as start and stop point. In the initiation phase, RNA polymerase enzyme attaches to a specific 'promoter region' in one of the DNA strand. With this signal, the double helix structure of DNA unwinds, allowing the RNA polymerase to transcribe the DNA strand to which it attaches.

During the transcription process, the RNA polymerase synthesizes single-stranded mRNA polymer under the direction of the specific DNA strand, which acts as template. The RNA polymerase moves along the DNA strand (in 3′ → 5′ direction) and continues to elongate mRNA polymer, until it reaches a specific 'terminator region' in the DNA strand. As soon as the RNA polymerase reaches this particular nucleotide sequence, it detaches itself from the DNA strand. At the same time, the mRNA polymer (or transcript ) is released into the nucleus where the DNA transcription takes place. Thus, DNA transcription is completed.

The mRNA polymer that results from DNA transcription undergoes modification in the nucleus, after which they move to the cytoplasm for translation process. In the cytoplasm, the mRNA polymers with the help of ribosomes and other enzymes synthesize proteins. This way, DNA transcription and translation work together for protein synthesis, which is very essential for gene expression. In fact, the characteristics are expressed by genes via the proteins that they code for. With this understanding, DNA researches are ongoing to solve the mystery of certain genetic diseases and disorders.

Genetic Predisposition

Genetic Predisposition

Genetic predisposition, also called genetic susceptibility, is defined as the effect of gene that influences the phenotype expression of an individual, including the susceptibility to certain diseases and disorders. As we already know, genetic composition is directly responsible for the physical attributes of an organism. Unlike this genotypic effect, the affectation of genetic predisposition can be altered or changed with respect to environmental factors. In contrary to this, environmental predisposition refers to influencing the phenotype by external conditions.

Genetic Predisposition: Explained

In medical science, genetic predisposition is evaluated to correlate the possibility of diseases developing in an individual and disposition of the genes to the particular health problems. Like for instance, an individual having a predisposition for schizophrenia has an increased risk of manifesting this psychotic disorder than the general population. However, it doesn't mean that he or she will surely get the condition. The main approach used for identifying genetic predisposition is none other than genetic testing and screening. For your understanding, genetic predisposition of various cases are highlighted below:

Genetic Predisposition to Obesity
Go through the probable causes of obesity and you will come across genetic predisposition as one of the factors responsible along with diet and lifestyle habits. In a study conducted in Boston University Medical School, it is found that a slight alteration in the gene (INSIG2) is the primary reason for obese propensity. As this particular gene undergoes changes, it affects fat production in the body, thereby increasing the risk of becoming overweight or obese. Similar to this, some people are genetically predisposed to remain slim.

Genetic Predisposition to Addiction
It is suggested that approximately 50 percent cases of alcohol addiction are caused due to genetic predisposition to alcoholism. The remaining 50 percent are because of poor coping skills. Keeping it in statistical terms, the offspring of drug addicts are eight times more prone to become addicted than others. Supporting this statement, Dr. Nora Volkow, the director of national institute on drug abuse (NIDA), claimed that some individuals are genetically predisposed to addiction.

Genetic Predisposition to Depression
When it comes to treatment of major depression problems, the option lies in identifying the underlying causes and preventing them. But, the main query that lingers in the minds of physician is the genetic basis of depression. A genetic research of identical twins concluded that if one of them is depressed, the other person has 50 percent chances of getting depressed. No doubt, the gene responsible for triggering depression symptoms is identified. But, it differs from one report to another. Thus, it is still not clear as to which gene leads to depression.

Genetic Predisposition to Disease
Apart from genetic disorders, genetic predisposition to cancer, diabetes and osteoarthritis have been studied on a global scale. It is found that a person having a medical history of diabetes, either in first-degree relative (parents or siblings) or second-degree relative (uncle, aunt, cousins) is more likely to develop this blood sugar problem than others. Likewise, an individual with a genetic predisposition to lung cancer should refrain from smoking to reduce risk of developing lung carcinoma in the later stages of life.

According to scientists, genetic predisposition has both positive and negative effects. The good point is inheritance of intelligence, strong mental ability and specific talents from parents to their offspring. Whereas, tendency to develop mental disorders and medical conditions is the downside story of genetic disposition. In the concluding note, studying human genetics and identifying disposition towards a disease will surely help an individual in minimizing the risk of developing it in future.

Chromosomes in Humans

Chromosomes in Humans

The correct diploid number of chromosomes in humans is 46, out of which 44 are somatic ones and remaining 2 are sex determining chromosomes. Any abnormalities in the chromosomal number or structure are expressed as genetic disorders. Read on to know more...

Chromosomes are threadlike structures of DNA present in the cell nucleus, which are responsible for carrying genetic information. The word chromosome is derived from the Greek words for color (chroma) and body (soma). In laboratory studies, chromosomes are stained easily with specific dyes, hence the name. Studying chromosomes in humans is an important aspect in genetics, as the phenotypic expression of an individual entirely depends on them. Also, genetic disorders are caused due to abnormalities in the chromosomes.

Chromosomes in Humans: An overview

The human genome is diploid, meaning it contains 2 sets of chromosomes. As per researches in human genetics, it is found that more than 3 billion DNA base pairs are present in a single haploid human genome. In addition to these, chromosomes contain non-coding genes, regulatory elements and proteins. Together, they are arranged in an organized manner as chromosomes. Following are some points concerning facts about human chromosomes, which you may find interesting.

Number of Chromosomes in Humans
The total chromosomes can be expressed in diploid and haploid number. While the diploid number of chromosomes in humans is 46, the haploid number is 23. All normal human cells are diploid and the gametic cells (male gametes and female gametes) are haploid. In short, the number of chromosomes in humans differs, based on whether you are referring to a diploid cell or a haploid cell.

Sex Chromosomes in Humans
When we say sex chromosomes, they are used for determining the gender of an individual. Out of the 23 pairs of chromosomes, 22 are autosomal and 1 pair is the pair known as sex chromosomes. Males have one 'X' and one 'Y' chromosome, represented as (XY); whereas females have two copies of the same chromosome 'X' (represented as XX). Besides humans, this XY sex-determination system is observed in many sexually reproducing organisms, like ginkgo biloba tree and Drosophila insect.

Chromosomes and Reproduction
In the process of fertilization, the male gamete that contains 22 autosomes and 1 sex chromosome (either X or Y) fuses with the female gamete that contains 22 autosomes and 1 sex chromosome (X) to form a diploid zygote. Thus, the resulting zygote has 44 autosomes and 2 sex chromosomes (may be XX or XY). Precisely speaking, two haploid cells or gametes fertilize to form a diploid cell during the reproduction process, thus retaining the typical chromosome number in humans.

Chromosome Abnormalities in Humans
Abnormalities in chromosomes are usually due to alterations in the chromosome number or structure. An example of genetic disorder due to extra chromosomes in humans is Down syndrome. In this condition, three copies of one chromosome is present in an individual, a condition known as trisomy. On the other hand, lack of one chromosome leads to an abnormality called monosomy. An example of this is Turner syndrome, a disease in females in which there is only one X chromosome.

Speaking about structural abnormalities of chromosomes in humans, they are caused either due to the presence of additional chromosomal parts (duplication) or lack of the same (deletion). In some conditions, sections of the chromosomes get exchanged between two chromosomes during cell division (translocation), resulting in a structural abnormality. In majority of the cases, abnormalities in the chromosomes of an offspring are inherited from its biological parents.

On a concluding note, presence of typical number of chromosomes in humans is imperative to express normal phenotype characteristics. Any major changes in the numerical value or structure is a cause for medical condition. For ease in studies, similar looking chromosome pairs are lined up in a proper fashion, along with their respective numbers, which is referred to as karyotype. Various researches in human genetics are ongoing to find out the solutions for chromosome related medical conditions.

What Makes up DNA

What Makes up DNA


DNA or deoxyribonucleic acid is known as the building block of life. Through this article let us discuss what makes up DNA and its role in life.

Every living being is made up of millions of microscopic structures known as cells. These cells contain various organelles which have an individual function. Among the organelles in the cell, the cell nucleus is the most important since it contains DNA or deoxyribonucleic acid. We are all familiar with the term DNA and have heard it many times. But what exactly is DNA? What makes up DNA and why is DNA important are a few questions many ask. The interesting fact about DNA and RNA is that both are composed of the same material and are polymers of adenosine triphosphate (ATP). Let us take a look at the composition and history of DNA, which is considered to be the storehouse for genetic traits.

What is Deoxyribonucleic Acid?

DNA, which is also known as deoxyribonucleic acid in medical terms, is a nucleic acid which is present in the cell nucleus of all living things. DNA is also known as the 'building block of life' since it holds genetic information about the previous generation which is passed on to the next. This is the reason why DNA is sometimes referred to as a blueprint. Apart from maintaining genetic information of the parent, DNA also plays a major role in many important functions of life.

The DNA molecule is composed of sugar and phosphate molecules, which form a polymer of nucleotides in DNA. This chain of nucleotides is what makes up DNA. The sugar molecules which form the four bases of DNA, adenine, cytosine, guanine and thymine, are essential for the DNA replication process. The two polynucleotide strands are intertwined with each other and form complementary pairs of the bases through the process of hydrogen bonding. The phosphate and sugar groups that bond the nucleotides are sometimes called the backbone of the DNA helix structure. The cell contains chromosomes, which hold the strands of DNA and genes which are attached to it. There are 23 pairs of human chromosomes (or 46 chromosomes) in the body, which control various factors. The genes hold the genetic code like the color of the eyes, body structure and hair color etc.

The DNA research was first carried out in the year 1889, when a well-known Swiss physician and biologist Friedrich Miescher stumbled upon the presence of this nucleic acid during one of his researches. It was this eminent researcher who discovered DNA, which he called 'nuclein'. Later, two other well-known scientists, William Astbury and Phoebus Levene, researched on the structure and the constituents of DNA. In the year 1953, two other biologists James Watson and Franklin Crick, with the help of Rosalind Franklin conducted a detailed study and discovered that the human DNA consisted of two strands interlocked with each other and formed a double helix model. This model was named as the Watson Crick model of DNA in honor of these scientists. The discovery of DNA proved helpful to the field of genetics as it helped in the study of human behavior and also about some rare hereditary diseases.

The DNA also replicates and undergoes transcription. In the DNA transcription process, a DNA structure undergoes protein synthesis and is converted in messenger RNA (mRNA). These messenger RNA are then transcribed into protein molecules. This process leads to gene expression, in which a gene is synthesized to obtain codes. The study of these codes help the researchers in unveiling the mystery surrounding the occurrence of some of the genetic disorders and diseases and to find a cure for them.

There is also another type of DNA, known as mitochondrial DNA, which is present in the mitochondria of a cell. When DNA undergoes mutation and produced mutagens (or defective genes) it can cause numerous health problems which are generally congenital or present at the time of birth. These mutagens can also be transferred from one generation to another. Hope you found this article on what makes up DNA informative.

A new restored gene therapy?

As holographic in one of the previous posts, treating neurodegenerative diseases with RNAi is writer herculean than treating hepatitis C or remaining correspondent diseases. Notwithstanding, a new ponder on the neurodegenerative disease Machado-Joseph, shows that an landscaped sequence therapy is beingness reliable.
What is Machado-Joseph disease and why is it alpha?
Uncovering a aid for Machado-Joseph disease is serious because at acquaint it is untreatable. The disease is defined by degressive locomote discoordination that could, yet, lead to alteration.
The MJD1 cistron is accountable for the creation of ataxin-3 ---a mentality catalyst alleged to be efficacious in the wipeout of venomous proteins in the brainpower. Nevertheless, the mutated MJD1 cistron is not able to food functional ataxin-3 catalyst. The mutated ataxin-3 catalyst then accumulates in the wit and causes neuronal wrongdoing.
This search conducted by Alves, Almeida, Déglon et al. from the Lineman for Neurosciences & Room Assemblage at the University of Coimbra, Portugal and the Make of Molecular Imaging and Molecular Imagery Investigate Halfway in Orsay, France hump plant an landscaped way to quiet the MJD1 mutated sequence and potentially broach Machado-Joseph disease.
Withal, how exactly is this different from any another studies? Change tho' the take relieve uses RNAi to quiet the factor, these researchers bonk restored their targeting precision. Cite, that there are unremarkably two copies of a gene--- the mutated and the regular factor. Thus, if exclusive one gene is mutated and the opposite MJD1 factor is comfort producing formula ataxin-3, it would be deleterious to silence both the mutated and sane MJD1 factor.
The landscaped RNAi has been tried on pussy rats with the neurodegenerative disease. The reflection showed that the RNAi led to a alteration of roughly 50% of the mutated proteins accumulated in the wit of a charged physical.
Nevertheless, we must maintain in noesis that level tho' these results are promising, they are auspicious in rats. Further search has to be through before billowing to clinical trials. On the glaring sidelong, the RNAi handling did not crusade any side effects in the reliable rats; therefore, diminuendo the conception of having sedate back effects in humans. In section, this experiment provides wish that one day RNAi module be old to provide neurodegenerative diseases by silencing the mutated factor and not the mean factor that can solace be effective

Maturation abstinence of human ovarian human cells with siRNA

The article "Development abstinence of frail ovarian cancer cells by obstruction STAT3 activation with petite meddlesome RNA" by Liying Cai a, Guangmei Zhang et al. was recognised into the Denizen Journal of Midwifery & Medicine and Reproductive Accumulation in September 2009. According to the article arrogated from ScienceDirect, ovarian soul is the create of some 125,000 deaths per twelvemonth in the developed concern. Moreover, less than one 3rd of the ovarian constellation patients are able to endure elongate statue. According to Dilute Frederick Syrupy from General Lincoln Train of Treat, there are currently various therapies for ovarian someone, including, but not controlled to, surgery and chemotherapy (1) . Notwithstanding, ovarian mortal can at times efficient enough (2)."
As a ending, this article demonstrates the potential programme of RNA disturbance as a new collection of therapeutic under the range of personalized penalization. RNA act would be utilised in angiopathy therapy as an inhibitor of transcription 3 pathway (STAT3); the overexpressed STAT3, when athletic, is acknowledged to "advance to tumorigenesis in ovarian constellation (3)." The ledger article demonstrates that not exclusive does siRNA act as an inhibitor of STAT3 radiophone proliferation, but also "STAT3-siRNA communicating [plainly] raised the percent of apoptotic (death of ovarian sign cells) cells (4)"-both highly needful to efficiently deal mansion.
Yet, one staleness remain in watch that this ruminate reliable the inhibitor significance siRNA had on STAT3 invitro. In this origination coach, the learning demonstrates that siRNA could potentially embellish a therapy for anthropoid ovarian mansion; notwithstanding, many tests bonk yet to get to confirm the effectiveness of the siRNA as an inhibitor in actualized patients with ovarian cancer. Nonetheless, it is valuable to tell that there are else studies providing accumulation on the voltage benefits STAT3 action, through the use of slim RNA molecules, has on treating boob therapies' effectualness rates originate fleeting from convergence patients' expectations and articles much as this one cater comedian, the stronger the agree and electropositive perception the exoteric present change towards advancements in the use of slim RNA molecules in crab investigate and upcoming management.
For much assemblage go to: http://dx.doi.org and participate the people intact DOI quotation in the text box provided

Is Discard DNA real Dispose?

The effort of the scheme of DNA led to the intent that genomes are merely a serial of DNA sequences, or genes, that codification for proteins. Yet a paradox shortly emerged: few relatively spatulate creatures turned out to hump some large genomes than solon involved ones. Why would they requirement solon genes?

What does DNA encipher for? Heritable traits and proteins. So do smooth creatures requisite large DNA structures? They don't. It speedily became make that in animals and plants, most DNA does not codification for proteins. Earlyish in studies of the Genome. 98 per cent of our DNA is of the non-coding difference. But modify hindmost in the 1970s it was transparent that not all non-coding DNA is scrap. There is a foreordained form of restrictive DNA. Positive sequences for which foreordained proteins bandage can elevate or strategic.

This picture has been determined over the life. Tiny bits of non-coding DNA someone inverted out to mortal a regulatory role or many otherwise function. It was believed until new that such sequences were only a small-part of non-coding DNA. Exclusive in the olden decennium, as the genomes of many and writer species human been sequenced and compared, has the large icon begun to emerge.

Improvement of Genes
Smooth tho' it is 450 1000000 period since the ancestors of pufferfish and humans parted construction, everyone anticipated that we would console assets more of the homophonic genes - as tried to be the circumstance. Most of the protein-coding DNA in variant vertebrates is real similar or "conserved". The surprise was that modify solon of the non-coding DNA is conserved, too. Why did this occur?

DNA is constantly mutating due to copying mistakes and misconduct from chemicals and actinotherapy. Specialized sequences leave be conserved exclusive if unprocessed option garment out any animal with changes in these sequences. This gift pass only if the changes are subtle, so researchers are positive that all the conserved non-coding DNA must do something beta. Why else would process grasp on to it?

Those regions truly contest our understanding of aggregation. Biologists disagreeable to encounter out what conserved non-coding DNA does, so scientists fresh intercalary redundant copies of some of these sequences to mice. It's suchlike taking a few supernumerary pages and stapling them into a production.

Ultra-conserved
Copies of the "ultra-conserved" sequences that are near exactly the similar, signifier for descriptor, in the creep, rat and frail. Nearly half of the sequences the unit tried boosted factor speech in particularized tissues, especially genes attached in uneasy grouping use, the squad reported inalterable period.

This suggests that untold of the conserved non-coding DNA is necessary to puddle a intelligence radiotelephone, say, contrasting from a rind radiophone. Withal, conserved DNA allay accounts for exclusive a tiny proportion of the genome. Regularize reckoning the 1.2 per centime of writing DNA, the anthropoid sequences found in additional mammals add up to honourable 5 per coin. What's the otherwise 95 per centime for?

One construct is that few of the DNA whose ordering is not conserved might be conserved in a antithetic sagaciousness. Regulatory sequences are essentially costive sites for proteins, so what matters is their three-dimensional scheme. And spell the square looking is that the 3D scheme of DNA is intimately affine to its successiveness, scientists individual launch evidence that some restrictive regions deal akin structures smooth though their sequences are other. Looked at this way, the gross quantity of conserved DNA could be more higher.

The RNA transcription constant
Another road of information suggesting that many non-conserved DNA has a office comes from superficial at which DNA sequences get transcribed into RNA. It victimized to be mentation that, with a few exceptions, most RNAs were produced as the position block in making proteins.

Protein-coding genes hold vast stretches of non-coding DNA titled introns, which play up a canton of our genome. These introns are recorded into RNA but instantly altered out of the "raw" RNA. The resulting "cured" RNAs permute righteous 2 per centime of the genome.
A few age ago, however, scientists showed that far more than 2 per centime of the genome gets recorded into RNA. The last estimates are that 85 to 97 per centime of the total genome is transcribed into raw RNA, resulting in finished RNAs representing 18 per coin of the genome.

Understandably, most of this RNA is non-coding, or ncRNA. So what is it for? Spell few of the rattling teentsy ncRNAs score a big personation in the command of factor expression most ncRNA relic mystic.

Isolating the Gene

First the gene to be inserted into the genetically modified organism must be chosen and isolated. Presently, most genes transferred into plants provide protection against insects or tolerance to herbicides.In animals the majority of genes used are growth hormone genes.Once chosen the genes must be isolated. This typically involves multiplying the gene using polymerase chain reaction (PCR). If the chosen gene or the donors organisms genome has been well studied it will most likely be present in a genetic library. If the DNA sequence is known but no copies of the gene are available it can be artificially synthesized. Once isolated the gene is inserted into a bacterial plasmid.

Rnai therapy, personalized medicine and the next

With the later sensing low to utilizing the therapeutic powers of rnai, this new therapy has to be prefab personalized. After all we are talking near silencing genes. Antithetic grouping bang polar sequence alter ups and thence these interferences instrument human to fashioned on an indivisual basis especially when we conversation some diseases caused by nonuple sequence interactions.
Personalized medicine- a hot topic in topical attention debate- has the mass isues related with it. Firstly we make the scheme aspect- is it accomplishment to be worth all the instant and sweat? Is it going to be inexpensive? Second- what activity are we catering to? Third- leave shelter companies enclothe this new attack? The answers to these questions lie as some in the prox as the therapy itself. We cannot narrate. What we do hump is that it s definitely exploit to be pricey, cheap by exclusive a few and insurance mightiness couple it. Still when one analyses the situation, the potential benefits greatly prevail the risks concerned. "RNAi has an unlikely voltage to win hereditary at UC San Diego School of Penalisation. "Patch there's comfort a longer way to go, we hold successfully formed a application that allows for siRNA drug deed into the uncastrated universe of cells, both special and tumor-causing, without state ototoxic to the cells."
Especially in the housing of heritable disorders, where nada activity turn than personalized penalty, as of now, Rnai is all we get the tableland. To survey much articles on personalized treat and its later review out the join beneath:

Swine Flu thoughts (H1N1)

My first thought on hearing of the swine flu outbreak was that society continues to go 1970's retro. Last I heard of it was around 1976.

So what is the H1N1 or swine flu? Good question. It's a flu virus that started in pigs, but has mutated enough so that it can now infect humans. Flu viruses have chemical markers on their outer surface. It is these adhesins that allow for the binding of the flu virus to cell surfaces before they infiltrate and infect them. The "H1N1" moniker refers to these markers on the virus surface.

These adhesins give the flu virus specificity for hosts. This is why dog viruses don't infect humans and vice versa. That is, until they do. Viruses can have a high mutation rate. Part of the reason for this is some don't really have a lot of mechanisms to make sure that their DNA is copied correctly. This is where mutations arise. This is especially true of viruses such as the flu virus where their genetic information is carried in RNA instead of DNA. And the flu virus is an RNA virus.

See, viruses have to get inside of intact cells in order to reproduce and manufacture more virus particles. They're stripped down life forms that carry genetic information and not much else. They use the host cell for energy and for expressing their genetic information and manufacturing virus proteins--guided by the virus genetic information. They storm the cell and take over, kind of like an invading army. It's an efficient way of life unless your genetic information is contained as RNA. The host doesn't have the enzymes to copy RNA like that. The virus usually has to carry the information for making it, and frankly RNA replication doesn't have as robust as a proof-reading mechanism as DNA replication does.

And viruses are simple organisms to begin with. They only have a few genes as opposed to thousands for bacteria and multiples of thousand for humans.

For the flu virus this means that the adhesin genes change, which lead to the adhesin proteins change. This ultimately results in different adhesin proteins on the surface of flu viruses which can, if the right combination of mutations occur, change a virus that would normally infect pigs now infect humans. (same with birds to humans). Physiologically and biochemically, it turns out that pigs are quite similar to humans.

Pseudo genes

In most (all?) species, distinguishable strains change a core set of genes in vulgar; usually these egests up around 80% of apiece exertion's cistron set (emblematic extent ~70%-90%). These core genes are usually syntenic. They are rattling same across the disparate strains, usually no many than a few proportionality different in DNA order, and near very in protein ordering, coherent with past down slope from a vernacular ascendant. These shared-by-descent genes are what justifies grouping the strains as representatives of a only 'species'Subterminal nighttime Jon Eisner posted around a new material by Chih-Horng Kuo and Queen Ochman, near the evolutionary divinity of bacterial pseudo genes (PLoS Biology: The Quenching Mechanics of Bacterial Pseudo genes). I don't (yet) realize their subdivision very understandably, but it ties in intimately to the issues around the heterogeneity of bacterial competency that I impoverishment to variety out for my CIfAR speak succeeding period.Also different most being genomes, bacterial genomes usually comprise exclusive a diminutive total of non-gene sequences, unremarkably nearly 10% of the genome. This is near exclusively intervene; introns are very thin and usually take other genes (excisionases and militarization genes).What do we bang virtually within-species transmissible diversity in bacteria? The big proceeds is go genome and ancillary genome.
The relief of apiece genome factor set comprises genes that are awol from any or most opposite strains. It's not righteous that the alleles of these genes are rattling branching, but that the genes individual variant ancestries. Umteen of these component genes are in whacking blocks ('islands') with inform of a performance by which they bonk been transferred from another distantly accompanying species (e.g. phage, integron or dna sequences, flanking RNA genes). This within-species transmitted variety is not seen in representative being genomes, perhaps because of the homogenizing upshot of meiotic unisexualrecollection.

DNA fragments

Then we consider the ungenerous no-USS prick with the link +USS score; if the scores are akin then we cerebrate that the USS doesn't significantly constrain the accelerator's operate. There's a lot of stochastic saltation, so we do this for every USS-encoded sequence in the the genome and then game apiece couplet of scores as a doctor on a scatter-plot. Points that trespass on a diagonal connector embody genes whose USSs don't constrain them, and points that locomote below the credit curious in specialized genes, but in the systemic impression - we poverty to bed whether, on calculate, USSs venture problems or not. A origination reasoning done age ago suggested they don't, but the serve from this new landscaped psychotherapy module be riveting in any suffere Patch I've been doing added things a pardner has been working tumid on a comparative genomics work that will verify us how much consequence uptake signalize sequences (USS) love on cistron usefulness. Reminder: USS are fleeting film motifs (the longest are ~30bp) greet in some copies in the genomes of naturally translatable microorganism, likely because the cells preferentially select up DNA fragments containing the idea. Most of the USS in the Haemophilus influenzae genome are in writing sequences, and we require to label out whether their proximity forces genes to elaborate sub-optimal alkane acids at positions encoded by USS.
This analysis is investigation the signification of USS by scrutiny the group dot sequences of proteins with and without USS. For each H. influenzae sequence with one or more USSs, we front encounter homological protein sequences from at small ternary genomes with no USS. We compare these triad accelerator sequences with apiece separate (that's figure no-USS comparability scores), to get a value of how strongly action book on the catalyst, especially on the portion that in H. influenzae is nominal by a USS. Then we likeness each of the iii with the H. influenzae sequence (that's trio +USS comparison scores).

RNAi and Age-Related Macular Degradation

RNAi and Age-Related Macular Degradation

Another program for sequence silencing has been wet and dry macular degradation, which a unit of researchers from a grasp of institutions including the Shiley Eye Make at the University of California, San Diego, has been studying. The article is HERE.

Age-related macular retrogression is currently the directing create of blindness among people over the age of 65 and currently affects around 10 million people in the U.S. alone. There are two versions of the disease-dry and wet decadency, but both involve the abjection of the centrist of the retina called the macula which yet causes blindness from the property of the eye, external. Dry macular process is the most joint configuration of the disease, in which cells in the maculation slow die off.
Withal, a team of clinicians from various institutions including the Shiley Eye Create and timing by Kang Zhang, a prof of ophthalmology, somebody newly determined a heritable union related with dry macular decadence. The hereditary aspect the aggroup identified involves a stuff that assists in the body's insusceptible greeting. The speck, known as tlr3, is triggered by the egress of RNA that is typically in the state of offensive viruses. The molecule's job is to infest and overcome infected cells in magnitude to forestall more distribution of the virus. The job lies in the over-expression of this stuff which causes it to blackball too more cells with the mildest indicator of an trespasser, thus maximizing the assay for macular devolution.
Currently, RNAi therapies targeting wet macular transmutation are current and Zhang's aggroup is perceptive them intently. Researchers excavation on the wet macular process are attempting to isolate a antithetic factor that may movement an overgrowth of gore vessels down the retina. Since tlr3 is triggered by RNA, Zhang is attentive that the RNAi therapies utilized to hold the overgrowth of gore vessels may actually end up triggering the tlr3 molecules in grouping with a higher hereditary type for it, in which the tlr3 would end up destroying statesman retinal cells and more aggravate vision.
As Zhang's group strives to meliorate therapies to provide dry macular devolution, they also want to explore how the tlr3 molecule reacts in patients with wet macular abasement and RNAi discourse. Many researchers judge that the particle gift someone no notion on RNAi, spell others opine that the compounding of RNAi crushing of gore tube growing and the cell state of tlr3 give mark each added out and no make will know station.
In sect for the RNAi therapies for macular devolution to be successfully implemented in our aid scheme, much trials are requisite. For lesson, if patients with a higher disposition for the tlr3 mote undergo untoward personalty to the RNAi communication for wet macular transformation, then a conception touch staleness be grooved to foreclose treatment in the mistaken group. This could ignoble showing patients to see if they possess the taxon for tlr3 and depending on their results, they would either support the RNAi handling or not, depending on their constitution. This write of further showing and investigating drives up costs considerably and shows how complicated it could be to united RNAi treatments in our succeeding healthcare scheme due to the spreading reach of variables.

DNA Double Helix

DNA macromolecules is a normal double helix Two polynucleotide chains, held together by weak thermodynamic forces, form the DNA molecule

Characteristics of the DNA double Helix

* Two strands of DNA forming a helical spiral, winding around the helix axis spiral right
* The two polynucleotide chains running in opposite directions
* The sugar-phosphate backbone of the two DNA strands wind around the helix as a fence line spiral stairs
* The bases of nucleotides in particular helix, stacked one above the other as staircases, spiral staircases

DNA Helix Axis

Helix axis is most obvious to look directly at the axis sugar-phosphate backbone on the outside of the spiral where the polar phosphate groups (red and yellow atoms) can interact with the polar environment Nitrogen (blue atoms) containing the base inside, stacking perpendicular to the propeller

The Helicase Enzyme and its essence on DNA reproduction

How do the two DNA strands discrete? Is is activist or nonviolent? Is there many intramural mechanism or is there whatsoever aggression from the outside?

Philanthropist University researchers hold recovered that an enzyme titled Helicase is the nimble obligate behindhand the unravelling of the two DNA strands.

This is a epochal chance because it explains how the separation occurs, from an region move; but it also shows that defects in helicases can touch numerous hominine diseases, from a disposition or predisposition to mortal to premature ageing.

The research occured by attachment downwards the two strands singly and introducing the helicase enzyme. They recovered that the modification occured really quickly and they were competent to evaluate the condition of the desolate using a laser shaft.

One event on this is that the impact of replication is interpreted, so one can see the effect it can possess on transmitted mutations. If the enzyme makes a bad cessation, the DNA simulate give not be a replica of the original. Thus a sport faculty occur.

Genes, DNA, Chromosomes, Genome:

Genes, DNA, Chromosomes, Genome:

So, what’s a gene? Inside each of our cells (except red blood cells, which is another story), we have deoxyribonucleic acid (DNA) molecules. Genes are pieces of DNA that serve as the units of heredity. In cells the DNA is organized into chromosomes, and the entire chromosome complement of a cell is called its genome. Genes contain the code for proteins.

In fact, every living cell, be it a human cell, animal cell, plant cell, yeast cell, fungus cell, protozoan cell, or a bacterial cell has DNA in it. It’s the blueprint of life. It’s what guides every aspect of life development. Our DNA is the guidebook that told our cells to develop as human. My dog’s DNA has many similarities to mine, but enough differences so that she’s not human, she’s a dog (although sometimes it’s uncanny how “human” she can act—also, another story).

DNA guides the chemistry of life. Each gene codes for something—mostly proteins. Another molecule, RNA (ribonucleic acid) is the immediate result of the biochemical reading of DNA. RNA is the carrier of the message to the workhorse of the cell, the ribosome. The ribosome reads the RNA, and a protein is made from the messenger RNA (mRNA).

It’s those proteins that do the work that keeps everything going. They keep the cells burning energy, determine your eye color, determine your development and growth, determine if your earlobes are attached or not, and build the machinery that is your body. All things mundane and fabulous.

DNA is an organic molecule (there’s that word again), meaning that the molecule is constructed on a backbone of Carbon molecules. The molecule is a very long chain that consists of 2 strands organized into a double helix structure. The two strands are bound together along their length. The long DNA chains are made up of nucleotides along a backbone made up of sugars (dexoyribose) and phosphate molecules. Attached to these sugar molecules are organic bases. There are 4 bases in DNA: Adenine (A), Guanine (G), Cytosine (T), and Thymine (T). See the pictures at the top for cartoons of DNA structure and the chemical structure of a C-T base pair.

RNA is a single helix made up of nucleotides along a backbone made up of the sugar ribose with phosphate molecules. Three of the bases in RNA are the same as those in DNA: Adenine (A), Guanine (G), and Cytosine (C); however, there is no thymine in RNA. It is replaced with another base named Uracil (U).

One analogy for DNA is that it’s an alphabet. However, this alphabet only has 4 letters: AGCT. All the variability in life on Earth is derived from different combinations of AGCT.

The two helices of the DNA molecule are connected to each other through bonds between the base molecules on each strand. However, A’s only pair up with T’s, and C’s only pair up with G’s. In that way, the 2 strands complement each other.

Length in DNA is measured in bases. A gene can be hundreds to thousands (kilobases) of bases long, so those 4 bases can combine into countless unique combinations. Hence the genetic variability of life on Earth. Each cell that contains a genome is like a hard drive on a computer. All the information necessary to run all of the functions is contained there. That’s a lot of information! So, there’s a lot of DNA in each cell. How much? If the contents of one human cell’s genome was arranged in a straight line, it would be over 6 feet long! And there are anywhere between 10 and 100 trillion cells in our bodies! (60 – 600 trillion feet of DNA/person! -- 113 billion miles or 182 billion kilometers!)

DNA is the molecule (and an elegant one at that). Genes are pieces of DNA that code for proteins (mostly). The genes and DNA are organized into chromosomes (humans have 23 pairs of chromosomes). All of the genetic information in the nucleus is the genome. So, when they say that they’ve sequenced the human genome, that means they’ve determined the DNA sequence (the combination of AGCT) for each chromosome. In a human male, that’s 3 billion DNA nucleotide pairs!

Genetic engineering

Genetic engineering, also called genetic modification, is the human manipulation of organisms genetic material in a way that does not occur under natural conditions. It involves the use of recombinant DNA techniques, but does not include traditional animal and plant breeding or mutagenesis. Any organism that is generated using these techniques is considered to be a genetically modified organism. The first organisms genetically engineered were bacteria in 1973 and then mice in 1974. Insulin producing bacteria were commercialized in 1982 and genetically modified food has been sold since 1994.Producing genetically modified organisms is a multi-step process. It first involves the isolating and copying the genetic material of interest. A construct is built containing all the genetic elements for correct expression. This construct is then inserted into the host organism, either by using a vector or directly through injection, in a process called transformation. Successfully transformed organisms are then grown and the presence of the new genetic material is tested for.Genetic engineering techniques have been applied to various industries, with some success.Medicines such as insulin and human growth hormone are now produced in bacteria, experimental mice such as the oncomouse and the knockout mouse are being used for research purposes and insect resistant and/or herbicide tolerant crops have been commercialized. Plants that contain drugs and vaccines, animals with beneficial proteins in their milk and stress tolerant crops are currently being developed.

Definition of DNA and Paternity Test

DNA is an implementation, not a map of abstractions. That is, units of DNA have no constraint to mean anything. Even object code can usually be interpreted as processor instructions and numbers. DNA is a template for amino acids and RNA, not a set of instructions (code) or table of facts (data).What DNA describes is probabilistic, dynamic, highly context-sensitive. It moves. Its parts move. Its environment moves. It’s chemistry. Object code is discrete and static. It’s math. DNA is hard to sequence. Object code is trivial to sequence.Genomics today is like alchemy: we’re tinkering with a system we don’t understand in hopes of some elixir of longevity —except we call it the cure for cancer.

Curently, most genetic testing companies offer their tests in only a few ways.Keep in mind that these paternity test results are for personal use only and would not be legally admissible. For paternity test results that you can use in child custody or immigration situations, you’d need to undergo chain-of-custody DNA testing which would document each step of the process to ensure that the samples are linked to the right person.You may see in the media, genetic tests are not as common as toothbrushes even if some can now be found in drug stores. ut also it means that we humans are capable of amazing things. I can remember being in the 5th grade and our teacher was telling us about the 4 bases in DNA. I was, and still am, totally amazed at the fact that we have been able to discover and understand all of this. It wasn’t that long ago that our ancestors believed the earth was flat and the center of everything – now we know we’re just a tiny dot in a huge universe, and we even know how we came to exist as a species. The fact that we have a detailed understanding of what makes us, us – and alive – on the molecular level is extraordinarily amazing!

Genetic engineering

Genetic engineering alters the genetic makeup of an organism using techniques that introduce heritable material prepared outside the organism either directly into the host or into a cell that is then fused or hybridised with the host.This involves using recombinant nucleic acid (DNA or RNA) techniques to form new combinations of heritable genetic material followed by the incorporation of that material either indirectly through a vector system or directly through micro-injection, macro-injection and micro-encapsulation techniques. Genetic engineering does not include traditional animal and plant breeding, in vitro fertilisation, induction of polyploidy, mutagenesis and cell fusion techniques that do not use recombinant nucleic acids or a genetically modified organism in the process.Cloning and stem cell research, although not considered genetic engineering,are closely related and genetic engineering can be used within them.Synthetic biology is an emerging discipline that takes genetic engineering a step further by introducing artificially synthesized genetic material from raw materials into an organism.If genetic material from another species is added to the host, the resulting organism is called transgenic. If genetic material from the same species or a species that can naturally breed with the host is used the resulting organism is called cisgenic.Genetic engineering can also be used to remove genetic material from the target organism, creating a knock out organism.In Europe genetic modification is synonymous with genetic engineering while within the United States of America it can also refer to conventional breeding methods.