scholarly journals Preservation of Duplicate Genes by Complementary, Degenerative Mutations

Genetics ◽  
1999 ◽  
Vol 151 (4) ◽  
pp. 1531-1545 ◽  
Author(s):  
Allan Force ◽  
Michael Lynch ◽  
F Bryan Pickett ◽  
Angel Amores ◽  
Yi-lin Yan ◽  
...  
Keyword(s):  
Classical Model ◽  
Duplicate Gene ◽  
Regulatory Elements ◽  
The Other ◽  
Duplicate Genes ◽  
Duplicated Genes ◽  
Eukaryotic Genes ◽  
Gene Functions ◽  
New Gene ◽  
Gene Duplicates

Abstract The origin of organismal complexity is generally thought to be tightly coupled to the evolution of new gene functions arising subsequent to gene duplication. Under the classical model for the evolution of duplicate genes, one member of the duplicated pair usually degenerates within a few million years by accumulating deleterious mutations, while the other duplicate retains the original function. This model further predicts that on rare occasions, one duplicate may acquire a new adaptive function, resulting in the preservation of both members of the pair, one with the new function and the other retaining the old. However, empirical data suggest that a much greater proportion of gene duplicates is preserved than predicted by the classical model. Here we present a new conceptual framework for understanding the evolution of duplicate genes that may help explain this conundrum. Focusing on the regulatory complexity of eukaryotic genes, we show how complementary degenerative mutations in different regulatory elements of duplicated genes can facilitate the preservation of both duplicates, thereby increasing long-term opportunities for the evolution of new gene functions. The duplication-degeneration-complementation (DDC) model predicts that (1) degenerative mutations in regulatory elements can increase rather than reduce the probability of duplicate gene preservation and (2) the usual mechanism of duplicate gene preservation is the partitioning of ancestral functions rather than the evolution of new functions. We present several examples (including analysis of a new engrailed gene in zebrafish) that appear to be consistent with the DDC model, and we suggest several analytical and experimental approaches for determining whether the complementary loss of gene subfunctions or the acquisition of novel functions are likely to be the primary mechanisms for the preservation of gene duplicates. For a newly duplicated paralog, survival depends on the outcome of the race between entropic decay and chance acquisition of an advantageous regulatory mutation. Sidow (1996, p. 717) On one hand, it may fix an advantageous allele giving it a slightly different, and selectable, function from its original copy. This initial fixation provides substantial protection against future fixation of null mutations, allowing additional mutations to accumulate that refine functional differentiation. Alternatively, a duplicate locus can instead first fix a null allele, becoming a pseudogene. Walsh (1995, p. 426) Duplicated genes persist only if mutations create new and essential protein functions, an event that is predicted to occur rarely. Nadeau and Sankoff (1997, p. 1259) Thus overall, with complex metazoans, the major mechanism for retention of ancient gene duplicates would appear to have been the acquisition of novel expression sites for developmental genes, with its accompanying opportunity for new gene roles underlying the progressive extension of development itself. Cooke et al. (1997, p. 362)

Knockdown of duplicated zebrafishhoxb1genes reveals distinct roles in hindbrain patterning and a novel mechanism of duplicate gene retention

Development ◽  
2002 ◽  
Vol 129 (10) ◽  
pp. 2339-2354 ◽  
Author(s):  
James M. McClintock ◽  
Mazen A. Kheirbek ◽  
Victoria E. Prince
Keyword(s):  
Protein Function ◽  
Cranial Nerve ◽  
Duplicate Gene ◽  
Regulatory Elements ◽  
Duplicate Genes ◽  
Duplicated Genes ◽  
Gene Retention ◽  
Redundant Functions ◽  
Group 1 ◽  
Rhombomere 4

We have used a morpholino-based knockdown approach to investigate the functions of a pair of zebrafish Hox gene duplicates, hoxb1a and hoxb1b, which are expressed during development of the hindbrain. We find that the zebrafish hoxb1 duplicates have equivalent functions to mouse Hoxb1 and its paralogue Hoxa1. Thus, we have revealed a ‘function shuffling’ among genes of paralogue group 1 during the evolution of vertebrates. Like mouse Hoxb1, zebrafish hoxb1a is required for migration of the VIIth cranial nerve branchiomotor neurons from their point of origin in hindbrain rhombomere 4 towards the posterior. By contrast, zebrafish hoxb1b, like mouse Hoxa1, is required for proper segmental organization of rhombomere 4 and the posterior hindbrain. Double knockdown experiments demonstrate that the zebrafish hoxb1 duplicates have partially redundant functions. However, using an RNA rescue approach, we reveal that these duplicated genes do not have interchangeable biochemical functions: only hoxb1a can properly pattern the VIIth cranial nerve. Despite this difference in protein function, we provide evidence that the hoxb1 duplicate genes were initially maintained in the genome because of complementary degenerative mutations in defined cis-regulatory elements.

scholarly journals An Overview of Duplicated Gene Detection Methods: Why the Duplication Mechanism Has to Be Accounted for in Their Choice

Genes ◽  
2020 ◽  
Vol 11 (9) ◽  
pp. 1046
Author(s):  
Tanguy Lallemand ◽  
Martin Leduc ◽  
Claudine Landès ◽  
Carène Rizzon ◽  
Emmanuelle Lerat
Keyword(s):  
Genetic Material ◽  
Detection Methods ◽  
Duplicated Genes ◽  
Tool Selection ◽  
Genome Sequences ◽  
Gene Detection ◽  
Evolutionary Mechanism ◽  
Gene Functions ◽  
New Gene ◽  
Bioinformatic Approaches

Gene duplication is an important evolutionary mechanism allowing to provide new genetic material and thus opportunities to acquire new gene functions for an organism, with major implications such as speciation events. Various processes are known to allow a gene to be duplicated and different models explain how duplicated genes can be maintained in genomes. Due to their particular importance, the identification of duplicated genes is essential when studying genome evolution but it can still be a challenge due to the various fates duplicated genes can encounter. In this review, we first describe the evolutionary processes allowing the formation of duplicated genes but also describe the various bioinformatic approaches that can be used to identify them in genome sequences. Indeed, these bioinformatic approaches differ according to the underlying duplication mechanism. Hence, understanding the specificity of the duplicated genes of interest is a great asset for tool selection and should be taken into account when exploring a biological question.

scholarly journals DNA methylation signatures of duplicate gene evolution in angiosperms

2020 ◽  
Author(s):  
Sunil K. Kenchanmane Raju ◽  
S. Marshall Ledford ◽  
Chad E. Niederhuth
Keyword(s):  
Dna Methylation ◽  
Gene Evolution ◽  
Gene Dosage ◽  
Single Gene ◽  
Constitutive Expression ◽  
Duplicate Gene ◽  
Duplicate Genes ◽  
Whole Genome ◽  
Gene Duplicates ◽  
Methylation Patterns

ABSTRACTGene duplications have greatly shaped the gene content of plants. Multiple factors, such as the epigenome, can shape the subsequent evolution of duplicate genes and are the subject of ongoing study. We analyze genic DNA methylation patterns in 43 angiosperm species and 928 Arabidopsis thaliana ecotypes to finding differences in the association of whole-genome and single-gene duplicates with genic DNA methylation patterns. Whole-genome duplicates were enriched for patterns associated with higher gene expression and depleted for patterns of non-CG DNA methylation associated with gene silencing. Single-gene duplicates showed variation in DNA methylation patterns based on modes of duplication (tandem, proximal, transposed, and dispersed) and species. Age of gene duplication was a key factor in the DNA methylation of single-gene duplicates. In single-gene duplicates, non-CG DNA methylation patterns associated with silencing were younger, less conserved, and enriched for presence-absence variation. In comparison, DNA methylation patterns associated with constitutive expression were older and more highly conserved. Surprisingly, across the phylogeny, genes marked by non-CG DNA methylation were enriched for duplicate pairs with evidence of positive selection. We propose that DNA methylation has a role in maintaining gene-dosage balance and silencing by non-CG methylation and may facilitate the evolutionary fate of duplicate genes.

Genomic Background Predicts the Fate of Duplicated Genes: Evidence From the Yeast Genome

Genetics ◽  
2004 ◽  
Vol 166 (4) ◽  
pp. 1995-1999 ◽  
Author(s):  
Ze Zhang ◽  
Hirohisa Kishino
Keyword(s):  
Recombination Rate ◽  
Evolutionary Rate ◽  
Average Rate ◽  
Classical Model ◽  
Purifying Selection ◽  
Genomic Region ◽  
Yeast Genome ◽  
Duplicated Genes ◽  
Potential Force ◽  
Accelerated Evolution

Abstract Gene duplication with subsequent divergence plays a central role in the acquisition of genes with novel function and complexity during the course of evolution. With reduced functional constraints or through positive selection, these duplicated genes may experience accelerated evolution. Under the model of subfunctionalization, loss of subfunctions leads to complementary acceleration at sites with two copies, and the difference in average rate between the sequences may not be obvious. On the other hand, the classical model of neofunctionalization predicts that the evolutionary rate in one of the two duplicates is accelerated. However, the classical model does not tell which of the duplicates experiences the acceleration in evolutionary rate. Here, we present evidence from the Saccharomyces cerevisiae genome that a duplicate located in a genomic region with a low-recombination rate is likely to evolve faster than a duplicate in an area of high recombination. This observation is consistent with population genetics theory that predicts that purifying selection is less effective in genomic regions of low recombination (Hill-Robertson effect). Together with previous studies, our results suggest the genomic background (e.g., local recombination rate) as a potential force to drive the divergence between nontandemly duplicated genes. This implies the importance of structure and complexity of genomes in the diversification of organisms via gene duplications.

On the Modeling and Simulation of Friction

1991 ◽  
Vol 113 (3) ◽  
pp. 354-362 ◽  
Author(s):  
D. A. Haessig ◽  
B. Friedland
Keyword(s):  
Modeling And Simulation ◽  
Experimental Observation ◽  
Friction Force ◽  
Closed Loop ◽  
Physical Phenomenon ◽  
Classical Model ◽  
The Other ◽  
Simulation Experiments ◽  
New Models ◽  
Integrator Model

Two new models for “slip-stick” friction are presented. One, called the “bristle model,” is an approximation designed to capture the physical phenomenon of sticking. This model is relatively inefficient numerically. The other model, called the “reset integrator model,” does not capture the details of the sticking phenomenon, but is numerically efficient and exhibits behavior similar to the model proposed by Karnopp in 1985. All three of these models and the Dahl model are preferable to the classical model, which poorly represents the friction force at zero velocity. Simulation experiments show that the Karnopp model, the Dahl model, and the new models give similar results in two examples. In a closed-loop example, the classical model predicts a limit cycle which is not observed in the laboratory. The Karnopp model, the Dahl model, and the new models, on the other hand, agree with the experimental observation.

scholarly journals Actively translated uORFs reduce translation and mRNA stability independent of NMD in Arabidopsis

2021 ◽  
Author(s):  
Hsin-Yen Larry Wu ◽  
Polly Yingshan Hsu
Keyword(s):  
Gene Expression ◽  
Mrna Stability ◽  
Gene Expression Regulation ◽  
Regulatory Elements ◽  
Expression Regulation ◽  
Ribosome Profiling ◽  
Translation Efficiency ◽  
Nonsense Mediated Decay ◽  
Protein Levels ◽  
Eukaryotic Genes

ABSTRACTUpstream ORFs (uORFs) are widespread cis-regulatory elements in the 5’ untranslated regions of eukaryotic genes. Translation of uORFs could negatively regulate protein synthesis by repressing main ORF (mORF) translation and by reducing mRNA stability presumably through nonsense-mediated decay (NMD). While the above expectations were supported in animals, they have not been extensively tested in plants. Using ribosome profiling, we systematically identified 2093 Actively Translated uORFs (ATuORFs) in Arabidopsis seedlings and examined their roles in gene expression regulation by integrating multiple genome-wide datasets. Compared with genes without uORFs, we found ATuORFs result in 38%, 14%, and 43% reductions in translation efficiency, mRNA stability, and protein levels, respectively. The effects of predicted but not actively translated uORFs are much weaker than those of ATuORFs. Interestingly, ATuORF-containing genes are also expressed at higher levels and encode longer proteins with conserved domains, features that are common in evolutionarily older genes. Moreover, we provide evidence that uORF translation in plants, unlike in vertebrates, generally does not trigger NMD. We found ATuORF-containing transcripts are degraded through 5’ to 3’ decay, while NMD targets are degraded through both 5’ to 3’ and 3’ to 5’ decay, suggesting uORF-associated mRNA decay and NMD have distinct genetic requirements. Furthermore, we showed ATuORFs and NMD repress translation through separate mechanisms. Our results reveal that the potent inhibition of uORFs on mORF translation and mRNA stability in plants are independent of NMD, highlighting a fundamental difference in gene expression regulation by uORFs in the plant and animal kingdoms.

scholarly journals The evolution of regulatory elements in the emerging promoter variant strains of HIV-1

2021 ◽  
Author(s):  
Disha Bhange ◽  
Nityanand Prasad ◽  
Swati Singh ◽  
Harshit Kumar Prajapati ◽  
Shesh Prakash Maurya ◽  
...  
Keyword(s):  
Viral Latency ◽  
Regulatory Elements ◽  
The Other ◽  
Clinical Samples ◽  
Latent Reservoir ◽  
Viral Gene ◽  
Viral Promoter ◽  
Reservoir Characteristics ◽  
Hiv 1

AbstractIn a multicentric, observational, investigator-blinded, and longitudinal clinical study of 764 ART-naïve subjects, we identified nine different promoter-variant strains of HIV-1 subtype C (HIV-1C) emerging in the Indian population, with some of these variants being reported for the first time. Unlike several previous studies, our work here focuses on the evolving viral regulatory elements, not coding sequences. The emerging viral strains contain additional copies of the existing transcription factor binding sites (TFBS), including TCF-1α/LEF-1, RBEIII, AP-1, and NF-κB, created by sequence duplication. The additional TFBS are genetically diverse and may blur the distinction between the modulatory region of the promoter and the viral enhancer. In a follow-up analysis, we found trends, but not significant associations between any specific variant promoter and prognostic markers, probably because the emerging viral strains might not have established mono infections yet. Illumina sequencing of four clinical samples containing a co-infection indicated the domination of one strain over the other and establishing a stable ratio with the second strain at the follow-up time-points. Since a single promoter regulates viral gene expression and constitutes the master regulatory circuit with Tat, the acquisition of additional and variant copies of the TFBS may significantly impact viral latency and latent reservoir characteristics. Further studies are urgently warranted to understand how the diverse TFBS profiles of the viral promoter may modulate the characteristics of the latent reservoir, especially following the initiation of antiretroviral therapy.Significance StatementA unique conglomeration of TFBS enables the HIV-1 promoter to accomplish two diametrically opposite functions – transcriptional activation and transcriptional silencing. The various phases of viral latency - establishment, maintenance, and reversal - collectively determine the replication fitness of individual viral strains. A profound variation in the TFBS composition of the viral promoter may significantly alter the viral latency properties and the latent reservoir characteristics. Although the duplication of certain TFBS remains a quality unique to HIV-1C, the high-level genetic recombination of HIV-1 may promote the transfer of such molecular properties to the other HIV-1 subtypes. The emergence of several promoter-variant viral strains may make the task of a ‘functional cure’ more challenging in HIV-1C.

Induction of labial expression in the Drosophila endoderm: response elements for dpp signalling and for autoregulation

Development ◽  
1992 ◽  
Vol 116 (2) ◽  
pp. 447-456 ◽  
Author(s):  
G. Tremml ◽  
M. Bienz
Keyword(s):  
Reporter Gene ◽  
Regulatory Elements ◽  
The Other ◽  
Homeotic Gene ◽  
Signal Molecule ◽  
Response Elements ◽  
Extracellular Signal ◽  
Dependent Activity ◽  
Flanking Sequences ◽  
Drosophila Embryos

Extracellular signal proteins induce the homeotic gene labial (lab) to high levels of localised expression in the endoderm of Drosophila embryos. We aimed to identify cis-regulatory elements within the lab gene that respond to this induction by analysing the activity of stably integrated reporter gene constructs. Dissection of lab 5′ flanking sequences reveals two types of response elements. One of these mediates lab dependent activity, providing evidence that lab induction in the endoderm is autoregulatory. The other element, to a large extent independent of lab function, responds to decapentaplegic (dpp), a signal molecule related to mammalian TGF-beta. Our evidence suggests that lab induction in the endoderm reflects coordinate action of two distinct factors one of which may be lab protein itself, and another whose localised activity or expression in the midgut depends on the dpp signal.

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