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Basic Molecular Genetics for Epidemiologists F Calafell, N Malats 398 J Epidemiol Community Health: first published as 10.1136/jech.57.6.398 on 1 June 2003. Downloaded from GLOSSARY Basic molecular genetics for epidemiologists F Calafell, N Malats ............................................................................................................................. J Epidemiol Community Health 2003;57:398–400 This is the first of a series of three glossaries on CHROMOSOME molecular genetics. This article focuses on basic Linear or (in bacteria and organelles) circular DNA molecule that constitutes the basic physical molecular terms. block of heredity. Chromosomes in diploid organ- .......................................................................... isms such as humans come in pairs; each member of a pair is inherited from one of the parents. general increase in the number of epide- Humans carry 23 pairs of chromosomes (22 pairs miological research articles that apply basic of autosomes and two sex chromosomes); chromo- science methods in their studies, resulting somes are distinguished by their length (from 48 A to 257 million base pairs) and by their banding in what is known as both molecular and genetic epidemiology, is evident. Actually, genetics has pattern when stained with appropriate methods. come into the epidemiological scene with plenty Homologous chromosome of new sophisticated concepts and methodologi- cal issues. Each of the chromosomes in a pair with respect to This fact led the editors of the journal to offer the other. Homologous chromosomes carry the you a glossary of terms commonly used in papers same set of genes, and recombine with each other applying genetic methods to health problems to during meiosis. facilitate your “walking” around the journal Sex chromosome issues and enjoying the articles while learning. Sex determining chromosome. In humans, as in Obviously, the topics are so extensive and inno- all other mammals, embryos carrying XX sex vative that a single short glossary would not be chromosomes develop as females, whereas XY sufficient to provide you with the minimum embryos develop as males. The X and Y chromo- amount of molecular and genetic concepts to somes contain different, partly overlapping sets of range over the whole field. Hence, we have organ- genes. ised the manuscript in three short glossaries that will try to guide you from the most basic molecu- lar terms (the first glossary, published in this CODON issue) to the most advanced genetic terms, most Each of the 64 different nucleotide triplets in DNA of them related to new study designs and labora- that, when transcribed into RNA, are then tory techniques (the last glossary). translated into an aminoacid in a protein. For β http://jech.bmj.com/ We have attempted to provide concise defini- example, the haemoglobin gene starts with the tions and some examples of the most used DNA sequence ATGGTG... (that is, with the ATG concepts and designs in genetic epidemiology GTG ... codons), which is then transcribed into articles. Nevertheless, we are aware that the glos- the messenger RNA sequence AUG GUG..., which saries are not exhaustive and we refer the reader means that the haemoglobin protein sequence to other texts.1–4 will start with aminoacids MetVal... Codon ATG This initiative does not pretend to cover always corresponds to aminoacid methionine in concepts in molecular epidemiology as this would the corresponding protein, GTG to valine, and so on September 25, 2021 by guest. Protected copyright. require a list of terms as large as the one the 64 different codons map to the 20 different presented here. However, as the two areas are aminoacids. This correspondence table is called related, some of the concepts used by molecular the genetic code. Often, all four codons that differ epidemiology are defined here, too. In some cases, only in their third nucleotide code for the same a single term may be used in both scenarios with aminoacid; thus, most DNA sequence changes slightly different meanings (for example, marker). affecting the third position in a codon do not change the resulting protein. ALLELE Stop codon Each of the different states found at a polymorphic Codon signalling the end of the coding portion of site. Different alleles and their combinations may a gene. In mammals, stop codons are TGA, TAA, result in different phenotypes. For example, the and TAG. ABO gene contains three major alleles, A, B, and See end of article for O; AA and AO individuals express the A blood DNA (DESOXYRIBONUCLEIC ACID) authors’ affiliations group; BB and BO express B; AB appear as AB, Macromolecule that constitutes the basis of ....................... and only OO individuals express the O blood heredity. It is a double helix made up of four dif- Corresponcence to: group. ferent types of subunits or nucleotides: adenine, Francesc Calafell, Carrer guanine, cytosine, and thymine (or A, G, C, and del Dr Aiguader 80, T). Each nucleotide is made of a different base, E-08003 Barcelona, Spain; [email protected] AUTOSOME plus phosphate and the desoxyribose sugar. ....................... Non-sex chromosome. Nucleotides in each strand of the helix face www.jech.com Molecular genetics 399 J Epidemiol Community Health: first published as 10.1136/jech.57.6.398 on 1 June 2003. Downloaded from nucleotides in the other in a complementary way: A bonds GERM LINE with T and G with C; the sequence in one strand of the double Cell lineage that, after a number of divisions and meiosis, leads helix effectively determines the sequence in the other strand. to the production of the gametes (sperm or ova). Mutations in DNA is replicated semi-conservatively by enzymes known as the germline can be passed on to the offspring. DNA polymerases that open the double helix and bind together two new strands by inserting the appropriate complementary nucleotides. Sections of DNA (see genes) are HETEROZYGOTE transcribed into RNA, which is then used as a template to Individual that carries two different alleles at the same site in build proteins: the DNA sequence is effectively decoded and the two homologous chromosomes of a given pair. translated into a protein. HOMOZYGOTE Coding DNA Individual that carries two copies of the same alleles at the DNA that actually carries genetic information. It is just 3% of same site in the two homologous chromosomes of a given pair. the total DNA. Junk DNA INTRON DNA that does not seem to have any function. In fact, the Each of the segments of a gene that are not transcribed into human genome is riddled with sequences that derive from messenger RNA and that are found between exons. non-pathogenic viruses that inserted their DNA into the human genome, and that have been inadvertently copied ever since. LOCUS Any given genome region Mitochondrial DNA (mtDNA) Small circular DNA molecule contained in the mitochondria. MICROSATELLITE (SYNOMYN, SHORT TANDEM mtDNA is 16 500 basepairs long, just a small fraction of the REPEAT, STR) 3200 million bp in the nuclear genome. Each mitochondrion DNA segment consisting in the repetition 5–50 times of a in a cell carries tens of mtDNA copies, usually identical (a motif 1–6 basepairs long. Microsatellites tend to be polymor- situation called homoplasmy) but not always so (heteroplasmy). phic in their number of repetitions because of a high mutation Some disease causing mutations in mtDNA are only found in rate. DNA polymerases tend to “slip” when copying microsat- heteroplasmy as they would be lethal in homoplasmy. mtDNA ellite tracts, adding or subtracting repeat units. Given their codes for some of the proteins in the respiratory chain, the high polymorphism, microsatellites are widely used in core of the energy producing cellular machinery that resides in mapping genetic diseases, in genetic counselling, in forensic mitochondria. It seems that mtDNA from the sperm cells does genetics, and in population genetics. not penetrate the ovum, being mtDNA inherited solely from the maternal line. MUTATION Non-coding DNA Any change in a DNA sequence arising from an error in the DNA that is not transcribed into RNA, and, thus, not duplication process. In a clinical sense, any such change that translated into protein. Non-coding DNA can have other func- disrupts the information contained in DNA and leads to tions, such as acting as a signal to modulate the expression of disease. The mechanisms leading to mutations are diverse: a particular gene. from exogen and endogen carcinogens to DNA repair defects. http://jech.bmj.com/ Nuclear DNA Frameshift mutation DNA contained in the nucleus of the cell; in fact, all but the Indel mutation that disrupts the reading frame within a gene. mitochondrial DNA is nuclear. For example, ATG GTG CAC CTG ACT translates into protein sequence MetValHisLeuThr, whereas, ifaCisinserted in the fourth position, the reading frame becomes ATG CGT GCA EPIGENETIC EFFECT CCT GAC T, which reads MetArgAlaProAsp—that is, a Change in the outcome of a particular gene that is not completely different protein and likely to be non-functional. controlled genetically. DNA methylation is one such change, on September 25, 2021 by guest. Protected copyright. which can turn off the expression of some genes. Gain of function mutation Mutation resulting in a protein having a different function EXON from the original. Each of the segments in a gene that are transcribed, and whose transcripts are spliced together to form the messenger RNA.In Germline mutation some cases, different proteins can be coded by the same gene Any mutation occurring in the germ line and transmitted to the by alternative splicing, that is, by different combinations of offspring. exons forming different messenger RNAs, and, therefore, being translated into different proteins. Indel mutation Mutation that consists in the insertion (addition) or deletion GENE of one or a few nucleotides DNA segment that is transcribed into messenger RNA and Missense mutation translated into a protein. Genes comprise the exons that are Nucleotide substitution that changes one codon for another actually translated plus the intervening introns.
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