Mitochondrial pseudogenes in the nuclear genomes of Drosophila

Mitochondrial pseudogenes in nuclear chromosomes (numts) have been detected in the genomes of a diverse range of eukaryotic species. However, the numt content of different genomes and their properties is not uniform, and study of these differences provides insight into the mechanisms and dynamics of genome evolution in different organisms. In the genus Drosophila, numts have previously only been identified on a genome-wide scale in the melanogaster subgroup. The present study extends the identification to 11 species of the Drosophila genus. We identify a total of 302 numts and show that the numt complement is highly variable in Drosophilids, ranging from just 4 in D. melanogaster to 67 in D. willistoni, broadly correlating with genome size. Many numts have undergone large-scale rearrangements in the nucleus, including interruptions, inversions, deletions and duplications of sequence of variable size. Estimating the age of the numts in the nucleus by phylogenetic tree reconstruction reveals the vast majority of numts to be recent gains, 90% having arisen on terminal branches of the species tree. By identifying paralogs and counting duplications among the extant numts we estimate that 23% of extant numts arose through post-insertion duplications. We estimate genus average rates of insertion of 0.75 per million years, and a duplication rate of 0.010 duplications per numt per million years.     

Processed pseudogenes for rat cytochrome c are preferentially derived from one of three alternate mRNAs.

Three cytochrome c mRNAs (1,400, 1,100 and 700 nucleotides) are colinear with RC4, a gene that has introns and correctly encodes cytochrome c. A comparison of RC4 to six nonallelic clones isolated from the rat cytochrome c multigene family demonstrates that all three mRNAs are represented in the genome as processed pseudogenes. Four of the six pseudogenes are derived from the 1,100-nucleotide mRNA, and genomic hybridizations further establish that nearly all of the 30 or so gene family members are also genomic copies of this mRNA despite the equimolar ratio of the three messages in rat tissues. Thus, the surprising multiplicity of cytochrome c sequences in the rat genome is mainly accounted for by the selective use of the 1,100-nucleotide mRNA for the formation of processed pseudogenes. In contrast to 700- and 1,400-nucleotide species which are polyadenylated downstream from AAGUAAA and AAUUAAA, respectively, the 1,100-nucleotide mRNA uses the ubiquitous AAUAAA and also displays a unique stem and loop structure (delta G = -59.4 kJ) centered 37 base pairs upstream from this sequence.     

Processed pseudogenes are located preferentially in regions of low recombination rates in the human genome

The aim of this article is to demonstrate possible recombination‐associated evolutionary forces affecting the genomic distribution of processed pseudogenes. The relationship between recombination rate and the distribution of processed pseudogenes is analysed in the human genome. The results show that processed pseudogenes preferentially accumulate in regions of low recombination rates and this correlation cannot be explained by indirect relationships with GC content and gene density. Several explanatory models for the observation are discussed. A model of selection against ectopic recombination is tested based on the difference in distribution pattern between two classes of processed pseudogenes, which differ in the possibility of stimulating ectopic recombination. Our results indicate that the correlation between processed pseudogene density and recombination rate is probably results, in part, from the selection against ectopic recombination between closely located homologous processed pseudogenes. We also found a length effect in processed pseudogene distribution, namely long processed pseudogenes are located more preferentially in regions of low recombination rates than short ones.     

Antifreeze protein pseudogenes.

Three members, 11-3, F2 and 5a, of the type-I antifreeze protein (AFP) multigene family in winter flounder were sequenced. All three belong to the subset of AFP genes that are linked, but irregularly spaced, and show significant differences from the functional genes in tandem repeats. 11-3 and F2 appear to be pseudogenes. Their intron, 3'-exon and 3'-flanking DNAs are similar to those of other AFP genes, but their 5'-exon is either missing or extensively modified, and has stop codons present in all three reading frames. Based on a comparison of intron sequences of family members, 11-3/F2 may represent a residual progenitor AFP gene which was duplicated after reaching pseudogene status. The third gene, 5a, is remarkable in having a 3'-exon that encodes an exceptionally long, Ala-rich sequence that lacks any semblance of the 11-amino acid repeats found in 11-3, F2 and functional AFP genes. 5a might also be a pseudogene, because its presumed TATA box appears to have mutated.     

Examination of four HLA class I pseudogenes. Common events in the evolution of HLA genes and pseudogenes.

The HLA class I gene family in lymphoblastoid cell line 721 has been studied in detail and a number of sequences in addition to the classical genes have been identified. The cloning, characterization, and nucleotide sequences of four sequences, all full length HLA class I pseudogenes, are described in this report. These pseudogenes, contained within 5.4-, 5.9-, 7.0-, and 9.2-kb HindIII fragments, each have the class I exon-intron structure as well as class I homology in their 5' and 3' flanking regions. However, all four sequences have one or more substitutions that perturb the coding region, leaving little doubt that they are in fact pseudogenes. Comparisons among these sequences and the HLA class I genes revealed that their homology with the class I genes is patchwork. Thus, although some regions have diverged, other contiguous intron-exon sequences are highly conserved. Comparisons in the 5' regions indicate that the pseudogene promoters more closely resemble the classical HLA promoters than the nonclassical promoters as none of the unique structural features found in the HLA-E, -F, or -G regulatory regions are present in any of the pseudogene promoters. Further comparisons revealed that at least two putative gene conversion events, similar to those hypothesized to have occurred in the evolution of some HLA genes, may have occurred in the evolution of some of the pseudogenes. These and other hypothetical events in the evolution of the class I gene family are discussed.     

Vertebrate pseudogenes

Pseudogenes are commonly encountered during investigation of the genomes of a wide range of life forms. This review concentrates on vertebrate, and in particular mammalian, pseudogenes and describes their origin and subsequent evolution. Consideration is also given to pseudogenes that are transcribed and to the unusual group of genes that exist at the interface between functional genes and non-functional pseudogenes. As the sequences of different genomes are characterised, the recognition and interpretation of pseudogene sequences will become more important and have a greater impact in the field of molecular genetics.     

Human dopamine D5 receptor pseudogenes.

Molecular cloning studies have now identified five structurally homologous genes encoding the biosynthesis of the human dopamine receptors, DRD1, DRD2, DRD3, DRD4, and DRD5. Two of these dopamine receptors (DRD1 and DRD5) are encoded by intronless genes. To ascertain whether there are other intronless genes that share identity with the gene (DRD5) encoding the DRD5 receptor, we used a cloning method based on the polymerase chain reaction (PCR). Human genomic DNA was amplified by PCR with oligodeoxyribonucleotides (oligos) based on the DRD5 nucleotide (nt) sequence. Amplification of nt sequences between these oligos allowed the isolation of two independent intronless genes that share identity with DRD5. The full-length clones have also been isolated by screening human genomic libraries. The deduced amino acid sequences for these genes, PG-1 and PG-2, share 91% and 92% identity to DRD5, respectively. However, each of the genes contains differences in the coding regions that would render these genes incapable of encoding functional receptors. Thus, the human genome contains at least two DRD5 pseudogenes, consistent with in situ human chromosomal hybridization analysis which reveals the presence of two pseudogenes.     

mRNA surveillance of expressed pseudogenes in C. elegans

Messenger RNAs (mRNAs) that contain premature translation termination codons (PTCs) are targeted for rapid degradation in all eukaryotes tested. The mechanisms of nonsense-mediated mRNA decay (NMD) have been described in considerable detail, but the biological roles of NMD in wild-type organisms are poorly understood. mRNAs of wild-type organisms known to be degraded by NMD ("natural targets" of NMD) include by-products of regulated alternative splicing, out-of-frame mRNAs derived from unproductive gene rearrangements, cytoplasmic pre-mRNAs, endogenous retroviral and transposon RNAs, and mRNAs having upstream open reading frames or other unusual sequence features. NMD may function to eliminate aberrant PTC-containing mRNAs in order to protect cells from expression of potentially deleterious truncated proteins. Pseudogenes are nonfunctional genes or gene fragments that accumulate mutations through genetic drift. Such mutations will often introduce shifts of reading frame and/or PTCs, and mRNAs of expressed pseudogenes may thus be substrates of NMD. We demonstrate that mRNAs expressed from C. elegans pseudogenes are degraded by NMD and discuss possible implications for both mRNA surveillance and protein evolution. We describe an expressed pseudogene that encodes a small nucleolar RNA (snoRNA) within an intron and suggest this represents an evolutionary intermediate between snoRNA-encoding host genes that do or do not encode proteins.     

Nuclear mitochondrial pseudogenes

As has been demonstrated recently, the transfer of genetic material from mitochondria to the nucleus and its integration into the nuclear genome is a continuous and dynamic process. Fragments of mitochondrial DNA (mtDNA) are incorporated in the nuclear genome as noncoding sequences, which are called nuclear mitochondrial pseudogenes (NUMT pseudogenes or NUMT inserts). In various eukaryotes, NUMT pseudogenes are distributed through different chromosomes to form a “library” of mtDNA fragments, providing important information on genome evolution. The escape of mtDNA from mitochondria is mostly associated with mitochondrial damage and mitophagy. Fragments of mtDNA may be integrated into nuclear DNA (nDNA) during repair of double-strand breaks (DSBs), which are caused by endogenous or exogenous agents. DSB repair of nDNA with a capture of mtDNA fragments may occur via nonhomologous end joining or a similar mechanism that involves microhomologous terminal sequences. An analysis of the available data makes it possible to suppose that the NUMT pseudogene formation rate depends on the DSB rate in nDNA, the activity of the repair systems, and the number of mtDNA fragments leaving organelles and migrating into the nucleus. Such situations are likely after exposure to damaging agents, first and foremost, ionizing radiation. Not only do new NUMT pseudogenes change the genome structure in the regions of their integration, but they may also have a significant impact on the actualization of genetic information. The de novo integration of NUMT pseudogenes in the nuclear genome may play a role in various pathologies and aging. NUMT pseudogenes may cause errors in PCR-based analyses of free mtDNA as a component of total cell DNA because of their coamplification.     

Conservation and divergence of immunoglobulin VH pseudogenes.

The 12 immunoglobulin VH pseudogenes, that have been characterized to date, differ from most pseudogenes of other multigene families in two aspects: (i) they carry only one (11 cases) or at the most two (1 case) deleterious mutations and (ii) they show no evidence of increased divergence from intact VH genes. We describe here the first immunoglobulin VH pseudogene that does not have these characteristics. This pseudogene accumulated numerous deleterious mutations and diverged considerably from other genes of the VH gene family to which it belongs. In possible contrast to the other VH pseudogenes, this pseudogene seems to be selectively neutral. We discuss the implications of the characterization of this diverged VH pseudogene in relation to our understanding of the genetic mechanisms that generate diversity among germline immunoglobulin VH genes.     

假基因研究进展

假基因是功能基因的缺陷拷贝,它在序列结构上与功能基因非常相似,但已丧失了正常的蛋白质编码功能．假基因曾被认为是一类典型的非编码“垃圾DNA”,而如今人们发现假基因在基因表达调控和基因组进化过程中发挥着重要作用．从假基因的起源、序列结构特征、假基因的识别、假基因在染色体上的分布、分子进化规律,以及假基因功能等几个方面较为全面地介绍了该领域的最新研究进展．