Condition‐dependent mutation rates and sexual selection

‘Good genes’ models of sexual selection show that females can gain indirect benefits for their offspring if male ornaments are condition‐dependent signals of genetic quality. Recurrent deleterious mutation is viewed as a major contributor to variance in genetic quality, and previous theoretical treatments of ‘good genes’ processes have assumed that the influx of new mutations is constant. I propose that this assumption is too simplistic, and that mutation rates vary in ways that are important for sexual selection. Recent data have shown that individuals in poor condition can have higher mutation rates, and I argue that if both male sexual ornaments and mutation rates are condition‐dependent, then females can use male ornamentation to evaluate their mate’s mutation rate. As most mutations are deleterious, females benefit from choosing well‐ornamented mates, as they are less likely to contribute germline‐derived mutations to offspring. I discuss some of the evolutionary ramifications of condition‐dependent mutation rates and sexual selection.     

First evidence of pathogenicity of V234I mutation of hVAPB found in Amyotrophic Lateral Sclerosis

Amyotrophic Lateral Sclerosis is a motor neurodegenerative disease which is characterized by progressive loss of motor neurons followed by paralysis and eventually death. In human, VAMP-associated protein B (VAPB) is the causative gene of the familial form of ALS8. Previous studies have shown that P56S and T46I point mutations of hVAPB are present in this form of ALS. Recently, another mutation, V234I of hVAPB was found in one familial case of ALS. This is the first study where we have shown that V234I-VAPB does not form aggregate like other two mutants of VAPB and localizes differently than the wild type VAPB. It induces Ubiquitin aggregation followed by cell death. We propose that V234I-VAPB exhibits the characteristics of ALS in spite of not having the typical aggregation property of different mutations in various neurodegenerative diseases.     

Natural underlying mtDNA heteroplasmy as a potential source of intra‐person hiPSC variability

Functional variability among human clones of induced pluripotent stem cells (hiPSCs) remains a limitation in assembling high‐quality biorepositories. Beyond inter‐person variability, the root cause of intra‐person variability remains unknown. Mitochondria guide the required transition from oxidative to glycolytic metabolism in nuclear reprogramming. Moreover, mitochondria have their own genome (mitochondrial DNA [mtDNA]). Herein, we performed mtDNA next‐generation sequencing (NGS) on 84 hiPSC clones derived from a cohort of 19 individuals, including mitochondrial and non‐mitochondrial patients. The analysis of mtDNA variants showed that low levels of potentially pathogenic mutations in the original fibroblasts are revealed through nuclear reprogramming, generating mutant hiPSCs with a detrimental effect in their differentiated progeny. Specifically, hiPSC‐derived cardiomyocytes with expanded mtDNA mutations non‐related with any described human disease, showed impaired mitochondrial respiration, being a potential cause of intra‐person hiPSC variability. We propose mtDNA NGS as a new selection criterion to ensure hiPSC quality for drug discovery and regenerative medicine.     

Conformational and aggregation properties of the 1–93 fragment of apolipoprotein A‐I

Several disease‐linked mutations of apolipoprotein A‐I, the major protein in high‐density lipoprotein (HDL), are known to be amyloidogenic, and the fibrils often contain N‐terminal fragments of the protein. Here, we present a combined computational and experimental study of the fibril‐associated disordered 1–93 fragment of this protein, in wild‐type and mutated (G26R, S36A, K40L, W50R) forms. In atomic‐level Monte Carlo simulations of the free monomer, validated by circular dichroism spectroscopy, we observe changes in the position‐dependent β‐strand probability induced by mutations. We find that these conformational shifts match well with the effects of these mutations in thioflavin T fluorescence and transmission electron microscopy experiments. Together, our results point to molecular mechanisms that may have a key role in disease‐linked aggregation of apolipoprotein A‐I.     

Amino acid conservation and clinical severity of human glucose-6-phosphate dehydrogenase mutations

More than a hundred naturally occurring mutations of human glucose-6-phosphate dehydrogenase (G6PD) have been identified at the amino acid level. The abundance of distinct mutation sites and their clinical manifestations make this enzyme ideal for structure-function analysis studies. We present here a sequence and structure combined analysis by which the severity of clinical symptoms resulting from point mutations of this enzyme is correlated with quantified degrees of amino acid conservation within 23 G6PD sequences from different organisms. Our analysis verifies, on a quantitative basis, a widely held notion that clinically severer mutations of G6PD usually occur at conserved amino acids. However, marked exceptions to this general trend exist which are most notably revealed by a number of mutations associated with chronic nonspherocytic hemolytic anemia (class I variants). When mapped onto a homology-derived structural model of human G6PD, these class I mutational sites of low amino acid conservation appear to localize in two spatially distinct clusters, both of which are populated with mutations consisting mainly of clinically severer variants (i.e. class I and class II). These results of computer-assisted analyses contribute to a further understanding of the structure-function relationships of human G6PD deficiency.     

Functional characterization of human cancer-derived TRKB mutations

Cancer originates from cells that have acquired mutations in genes critical for controlling cell proliferation, survival and differentiation. Often, tumors continue to depend on these so-called driver mutations, providing the rationale for targeted anticancer therapies. To date, large-scale sequencing analyses have revealed hundreds of mutations in human tumors. However, without their functional validation it remains unclear which mutations correspond to driver, or rather bystander, mutations and, therefore, whether the mutated gene represents a target for therapeutic intervention. In human colorectal tumors, the neurotrophic receptor TRKB has been found mutated on two different sites in its kinase domain (TRKB(T695I) and TRKB(D751N)). Another site, in the extracellular part of TRKB, is mutated in a human lung adenocarcinoma cell line (TRKB(L138F)). Lastly, our own analysis has identified one additional TRKB point mutation proximal to the kinase domain (TRKB(P507L)) in a human melanoma cell line. The functional consequences of all these point mutations, however, have so far remained elusive. Previously, we have shown that TRKB is a potent suppressor of anoikis and that TRKB-expressing cells form highly invasive and metastatic tumors in nude mice. To assess the functional consequences of these four TRKB mutations, we determined their potential to suppress anoikis and to form tumors in nude mice. Unexpectedly, both colon cancer-derived mutants, TRKB(T695I) and TRKB(D751N), displayed reduced activity compared to that of wild-type TRKB. Consistently, upon stimulation with the TRKB ligand BDNF, these mutants were impaired in activating TRKB and its downstream effectors AKT and ERK. The two mutants derived from human tumor cell lines (TRKB(L138F) and TRKB(P507L)) were functionally indistinguishable from wild-type TRKB in both in-vitro and in-vivo assays. In conclusion, we fail to detect any gain-of-function of four cancer-derived TRKB point mutations.     

An overview of the mechanisms of mutagenesis and carcinogenesis

Cancer is a genetic disease due to the accumulation of numerous mutations rendering the tumour cell insensitive to control by the local cellular environment and by the whole organism. Analysis of the frequency of appearance of human cancer as a function of age shows that between four and seven mutations in key genes are usually necessary to produce most human cancers. Interesting debates in the literature are concerned with the idea that normal mutation rates followed by selective advantage of mutated clones are enough to produce the numerous mutations found in human cancers. Alternatively, the mutator phenotype hypothesis is based on the idea that the normal mutation rates are insufficient to account for the multiple mutations found in tumours. It is, however, difficult not only to know this exact mutation frequency in cells but also to know the total number of cell divisions giving rise to a cancer. Therefore, during at least one step in the carcinogenic process, a mutator phenotype in target cells may occur due to mutations controlling the fidelity of DNA replication or DNA repair, the apoptosis pathways or the cell cycle checkpoint regulations. Among the multiple mutations found in human cancers such as gene amplification, chromosome alterations and translocations, point mutations are very important and the molecular mechanisms of their production are well documented. I will describe in detail the various mechanisms that a cell can use to produce point mutations due to lower fidelity in the DNA polymerisation step or to inefficient repair pathways. The presence of multiple mutations in human cancer is interesting not only in terms of understanding the carcinogenesis process in humans but also in eventually promoting strategies to decrease the efficiency of this process and to increase cancer therapy regimen.     

Does premature aging of the mtDNA mutator mouse prove that mtDNA mutations are involved in natural aging?

Recent studies have demonstrated that transgenic mice with an increased rate of somatic point mutations in mitochondrial DNA (mtDNA mutator mice) display a premature aging phenotype reminiscent of human aging. These results are widely interpreted as implying that mtDNA mutations may be a central mechanism in mammalian aging. However, the levels of mutations in the mutator mice typically are more than an order of magnitude higher than typical levels in aged humans. Furthermore, most of the aging-like features are not specific to the mtDNA mutator mice, but are shared with several other premature aging mouse models, where no mtDNA mutations are involved. We conclude that, although mtDNA mutator mouse is a very useful model for studies of phenotypes associated with mtDNA mutations, the aging-like phenotypes of the mouse do not imply that mtDNA mutations are necessarily involved in natural mammalian aging. On the other hand, the fact that point mutations in aged human tissues are much less abundant than those causing premature aging in mutator mice does not mean that mtDNA mutations are not involved in human aging. Thus, mtDNA mutations may indeed be relevant to human aging, but they probably differ by origin, type, distribution, and spectra of affected tissues from those observed in mutator mice.     

Fine‐mapping natural alleles: quantitative complementation to the rescue

Mapping the genes responsible for natural variation and divergence is a challenging task. Many studies have mapped genes to genomic regions or generated lists of candidates, but few studies have implicated specific genes with a high standard of evidence. I propose that combining recent advances in genomic engineering with a modified version of the quantitative complementation test will help turn candidate genes into causal genes. By creating loss‐of‐function mutations in natural strains, and using these mutations to quantitatively fail‐to‐complement natural alleles, fine mapping should be greatly facilitated. As an example, I propose that the CRISPR/Cas9 system could be combined with the FLP/FRT system to fine‐map genes in the numerous systems where inversions have frustrated these efforts.     

Mismatch repair deficient human cells: spontaneous and MNNG-induced mutational spectra in the HPRT gene

We have determined both the spontaneous and N-methyl-N′-nitro-N-nitrosoguanidine (MNNG)-induced mutational spectra in the HPRT gene of human cells (MT1) defective in the mismatch repair gene hMSH6 (GTBP). Eight of nine exons and nine of sixteen intronic flanking sequences were scanned, encompassing >900 bp of the HPRT gene. Mutant hotspots were detected and separated by differences in their melting temperatures using constant denaturant capillary electrophoresis (CDCE) or denaturing gradient gel electrophoresis (DGGE).

A key finding of this work is that a high proportion of all HPRT inactivating mutations is represented by a small number of hotspots distributed over the exons and mRNA splice sites. Thirteen spontaneous hotspots and sixteen MNNG-induced hotspots accounted for 55% and 48% of all 6TG^R point mutations, respectively. MNNG-induced hotspots were predominantly G:C→A:T transitions. The spontaneous spectrum of cells deficient in hMSH6 contained transversions (A:T→T:A, G:C→T:A, A:T→C:G), transitions (A:T→G:C), a plus-one insertion, and a minus-one deletion. Curiously, G:C→A:T transitions, which dominate human germinal and somatic point mutations were absent from the spontaneous hMSH6 spectra.     

Origins of human mitochondrial point mutations as DNA polymerase gamma-mediated errors

Mitochondrial mutational spectra in human cells, tissues and derived tumors for bp 10,030-10,130 are essentially identical, suggesting a predominant mutagenic role for endogenous processes. We hypothesized that errors mediated by mitochondrial DNA polymerase gamma were the primary sources of mutations. Point mutations created in this sequence by human DNA pol gamma in vitro were thus compared to the eighteen mutational hotspots, all single base substitutions, previously found in human tissues. The set of concordant hotspots accounted for 83% of these in vivo mutational events. About half of these mutations are insensitive to prolonged heating of DNA during PCR and half increase proportionally with heating time at 98 degrees C. Primary misincorporation errors and miscopying errors past thermal denaturing products such as deaminated cytosines (uracils) thus appear to be of approximately equal importance. For the sequence studied, these data support the conclusion that, endogenous error mediated by DNA pol gamma constitutes the primary source of mitochondrial point mutations in human tissues.     

SEX REVERSAL: A FOUNTAIN OF YOUTH FOR SEX CHROMOSOMES?

Nonrecombining Y chromosomes are expected to degenerate through the progressive accumulation of deleterious mutations. In lower vertebrates, however, most species display homomorphic sex chromosomes. To address this, paradox I propose a role for sex reversal, which occasionally occurs in ectotherms due to the general dependence of physiological processes on temperature. Because sex‐specific recombination patterns depend on phenotypic, rather than genotypic sex, homomorphic X and Y chromosomes are expected to recombine in sex‐reversed females. These rare events should generate bursts of new Y haplotypes, which will be quickly sorted out by natural or sexual selection. By counteracting Muller's ratchet, this regular purge should prevent the evolutionary decay of Y chromosomes. I review empirical data supporting this suggestion, and propose further investigations for testing it.     

Familial hemiplegic migraine type 1 mutations W1684R and V1696I alter G protein-mediated regulation of CaV2.1 voltage-gated calcium channels

Familial hemiplegic migraine type 1 (FHM-1) is a monogenic form of migraine with aura that is characterized by recurrent attacks of a typical migraine headache with transient hemiparesis during the aura phase. In a subset of patients, additional symptoms such as epilepsy and cerebellar ataxia are part of the clinical phenotype. FHM-1 is caused by missense mutations in the CACNA1A gene that encodes the pore-forming subunit of Ca_V2.1 voltage-gated Ca^2 + channels. Although the functional effects of an increasing number of FHM-1 mutations have been characterized, knowledge on the influence of most of these mutations on G protein regulation of channel function is lacking. Here, we explored the effects of G protein-dependent modulation on mutations W1684R and V1696I which cause FHM-1 with and without cerebellar ataxia, respectively. Both mutations were introduced into the human Ca_V2.1α₁ subunit and their functional consequences investigated after heterologous expression in human embryonic kidney 293 (HEK‐293) cells using patch-clamp recordings. When co-expressed along with the human μ-opioid receptor, application of the agonist [d‐Ala2, N‐MePhe4, Gly‐ol]‐enkephalin (DAMGO) inhibited currents through both wild-type (WT) and mutant Ca_V2.1 channels, which is consistent with the known modulation of these channels by G protein-coupled receptors. Prepulse facilitation, which is a way to characterize the relief of direct voltage-dependent G protein regulation, was reduced by both FHM-1 mutations. Moreover, the kinetic analysis of the onset and decay of facilitation showed that the W1684R and V1696I mutations affect the apparent dissociation and reassociation rates of the Gβγ dimer from the channel complex, suggesting that the G protein-Ca^2 + channel affinity may be altered by the mutations. These biophysical studies may shed new light on the pathophysiology underlying FHM-1.     

Cancer‐associated mutations are preferentially distributed in protein kinase functional sites

Protein kinases are a superfamily involved in many crucial cellular processes, including signal transmission and regulation of cell cycle. As a consequence of this role, kinases have been reported to be associated with many types of cancer and are considered as potential therapeutic targets. We analyzed the distribution of pathogenic somatic point mutations (drivers) in the protein kinase superfamily with respect to their location in the protein, such as in structural, evolutionary, and functionally relevant regions. We find these driver mutations are more clearly associated with key protein features than other somatic mutations (passengers) that have not been directly linked to tumor progression. This observation fits well with the expected implication of the alterations in protein kinase function in cancer pathogenicity. To explain the relevance of the detected association of cancer driver mutations at the molecular level in the human kinome, we compare these with genetically inherited mutations (SNPs). We find that the subset of nonsynonymous SNPs that are associated to disease, but sufficiently mild to the point of being widespread in the population, tend to avoid those key protein regions, where they could be more detrimental for protein function. This tendency contrasts with the one detected for cancer associated‐driver‐mutations, which seems to be more directly implicated in the alteration of protein function. The detailed analysis of protein kinase groups and a number of relevant examples, confirm the relation between cancer associated‐driver‐mutations and key regions for protein kinase structure and function. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Mutational spectra in human B-cells. Spontaneous, oxygen and hydrogen peroxide-induced mutations at the hprt gene.

To test the hypothesis that reactive species in the oxygen cascade are responsible for spontaneous mutation, we examined the spectra of oxygen and hydrogen peroxide-induced mutations at the hprt locus in a human B-lymphoblastoid cell line. We compared these spectra with the spontaneous mutational spectrum. Large gene alterations were studied by Southern analysis of individual TGR clones. A combination of high fidelity polymerase chain reaction, denaturing gradient gel electrophoresis and direct DNA sequencing were used to detect and identify point mutations in exon 3 of hprt. With regard to spontaneous mutations, a previous study showed that 39% of the spontaneous TGR clones had large gene alterations. In the present study, the analysis of spontaneous point mutations within exon 3 revealed two hotspots. A one base-pair deletion (-A) at base-pair 256 or 257 and a two base-pair deletion (-GG) at base-pair 237 and 238, were detected in triplicate cultures. Each of the hotspots comprised about 1% of the TGR mutants. The analysis of individual oxygen-induced TGR clones (48 h, 910 microM-O2) showed 43% had large gene alterations similar to the spontaneous TGR clones. However, none of the spontaneous point mutation hotspots was found among triplicate oxygen-treated cultures. Two point mutations in common with H2O2-treated cultures were found in one of the three oxygen-treated cultures. Hydrogen peroxide-induced mutations (1 h, 20 microM) also differed from spontaneous mutations. Only 24% of the hydrogen peroxide-induced TGR clones had large gene alterations. The analysis of point mutations showed three hotspots within exon 3 of hprt. An AT to TA transversion at base-pair 259 had an average frequency of 3% of all TGR mutants (present in all of 3 H2O2-treated cultures). Two GC to CG transversions at base-pairs 243 and 202 were present at a frequency of 0.6% and 0.4%, respectively. A five base-pair deletion (base-pair 274 to 278) was present at an average frequency of 0.3%. The latter three mutations were detected in two of three H2O2-treated cultures. Thus, the point mutation spectra of both oxygen and hydrogen peroxide were significantly different from the spontaneous spectrum. The oxygen and hydrogen peroxide-induced spectra shared some features, suggesting that oxygen and hydrogen peroxide share some but not all pathways for induction of mutations within the DNA sequence studied here.(ABSTRACT TRUNCATED AT 400 WORDS)     

Die Immunsysteme der Bakterien

The immune systems of bacteria and important applications in biotechnology and medicine At the end of the 70s of the last century, a new technique has been developed allowing the synthesis of genes and the inducible expression of their recombinant proteins using restriction enzymes and vectors, mainly plasmids. This era has been designated as genetic engineering and is being replenished by the CRISPR‐Cas9 technology know as genome editing. This technology is about to revolutionize alterations in the genomes of all types of organisms, including bacteria, fungi, plants, animals and even humans. It allows the introduction and elimination of point mutations and even whole genes in all organisms. Important goals are the genetic optimization of crop plants and animals, fighting against cancer in humans and elimination of human viruses and pathogenic multi‐resistant bacteria. Important drawbacks are OFF‐targets which can cause mutations in any gene or influence their expression.     

Detection of point mutations in type I collagen by RNase digestion of RNA/RNA hybrids.

We have developed a strategy for the detection, localization and sequence determination of point mutations in the mRNA coding for the alpha 1(I) and alpha 2(I) chains of type I collagen. Point mutations are detected by RNase A cleavage of mismatches in RNA/RNA hybrids. The mRNAs coding for the fibrillar collagens present special problems for hybrid analysis because of their large size and their GC-rich and repetitive sequences. We have generated a series of overlapping antisense riboprobes covering the entire pro alpha 1(I) and pro alpha 2(I) mRNAs. Uniformly labelled normal antisense riboprobes are hybridized with the total fibroblast RNA of patients with possible mutations in type I collagen. Mismatches in the resulting RNA/RNA hybrids are cleaved with RNase A and the labelled riboprobe cleavage products are examined electrophoretically. The sensitivity and specificity of the system were demonstrated by the detection and localization of a known point mutation in the codon for alpha 1(I) glycine 988 (1). DNA for sequencing the mutations localized by hybrid analysis may be obtained by either (1) generation of a fibroblast cDNA library and isolation of both alleles by plaque screening, or (2) a more rapid method using first strand cDNA synthesis from poly (A+)-mRNA, followed by PCR amplification of the mutation-containing region of the DNA/RNA hybrid. This strategy for detection and isolation has wide application not only for mutations causing connective tissue disorders, but also for mutations in other large and repetitive genes. We have used this strategy for the detection and sequencing of a point mutation in alpha 2(I) mRNA associated with a case of lethal osteogenesis imperfecta. The G----A point mutation in the codon for alpha 2(I) glycine residue 805 results in the substitution of an aspartic acid at this position and is consistent with the proband's collagen protein data.     

Analysis of phylogenetically reconstructed mutational spectra in human mitochondrial DNA control region

Analysis of mutations in mitochondrial DNA is an important issue in population and evolutionary genetics. To study spontaneous base substitutions in human mitochondrial DNA we reconstructed the mutational spectra of the hypervariable segments I and II (HVS I and II) using published data on polymorphisms from various human populations. An excess of pyrimidine transitions was found both in HVS I and II regions. By means of classification analysis numerous mutational hotspots were revealed in these spectra. Context analysis of hotspots revealed a complex influence of neighboring bases on mutagenesis in the HVS I region. Further statistical analysis suggested that a transient misalignment dislocation mutagenesis operating in monotonous runs of nucleotides play an important role for generating base substitutions in mitochondrial DNA and define context properties of mtDNA. Our results suggest that dislocation mutagenesis in HVS I and II is a fingerprint of errors produced by DNA polymerase gamma in the course of human mitochondrial DNA replication     

Male age, germline mutations and the benefits of polyandry

The number of de novo mutations in the germline can be expected to increase with age in males, therefore females might decrease mutation load in their progeny by avoiding mating with older males. Here, I propose that female polyandry can be more effective in decreasing the risk of genetic disorders in progeny than pre‐copulatory mate choice, particularly if sperm competitiveness declines more steeply with age than other traits affecting chances of males to mate. If faster ageing of spermatogenic tissue causes older males to transfer inadequate numbers of functional sperm, polyandry would also benefit females directly.