Click here to close
Hello! We notice that you are using Internet Explorer, which is not supported by Xenbase and may cause the site to display incorrectly.
We suggest using a current version of Chrome,
FireFox, or Safari.
Sci Rep
2023 Feb 13;131:2512. doi: 10.1038/s41598-023-29800-9.
Show Gene links
Show Anatomy links
Acquisition of new function through gene duplication in the metallocarboxypeptidase family.
Fajardo D
,
Saint Jean R
,
Lyons PJ
.
Abstract
Gene duplication is a key first step in the process of expanding the functionality of a multigene family. In order to better understand the process of gene duplication and its role in the formation of new enzymes, we investigated recent duplication events in the M14 family of proteolytic enzymes. Within vertebrates, four of 23 M14 genes were frequently found in duplicate form. While AEBP1, CPXM1, and CPZ genes were duplicated once through a large-scale, likely whole-genome duplication event, the CPO gene underwent many duplication events within fish and Xenopus lineages. Bioinformatic analyses of enzyme specificity and conservation suggested a greater amount of neofunctionalization and purifying selection in CPO paralogs compared with other CPA/B enzymes. To examine the functional consequences of evolutionary changes on CPO paralogs, the four CPO paralogs from Xenopus tropicalis were expressed in Sf9 and HEK293T cells. Immunocytochemistry showed subcellular distribution of Xenopus CPO paralogs to be similar to that of human CPO. Upon activation with trypsin, the enzymes demonstrated differential activity against three substrates, suggesting an acquisition of new function following duplication and subsequent mutagenesis. Characteristics such as gene size and enzyme activation mechanisms are possible contributors to the evolutionary capacity of the CPO gene.
Figure 1. A history of gene duplication is shown by protein sequence similarities, gene synteny, and structural conservation within the M14 family of metallocarboxypeptidases. (a) A phylogenetic tree showing the relationships of the core catalytic domains of all human M14 proteins, clearly indicating the three major subfamilies (A/B, N/E, and CCP). Outgroups used for this tree were the aminoacylases, ASPA and ACY3, considered by some to be a fourth, although quite distant, subfamily of MCPs. Bootstrap values are shown at key nodes. Scale bar indicates substitutions per site. The CPD protein contains three tandem carboxypeptidase domains, hence this protein is represented by three branches. (b) The chromosomal location of each metallocarboxypeptidase gene. Those showing a tandem arrangement, suggestive of recent duplications, are shown in red with arrows below indicating their precise synteny. CPXM1 and CPD are duplicated in the zebrafish genome, thus two chromosomes are indicated. (c) Representative structures are shown for each of the three subfamilies of metallocarboxypeptidases, illustrating their homologous CP domains, yet different N- and C-terminal domains. Human CPA2 (1AYE) from the CPA/B subfamily, duck CPD2 (1QMU) from the CPN/E subfamily, and Pseudomonas aeruginosa cytosolic carboxypeptidase (4A37) representing the CCP subfamily.
Figure 2. Several genes within the M14 family are further duplicated within many species. All orthologs of human M14 metallocarboxypeptidases of the (a) A/B subfamily, (b) N/E subfamily, and (c) CCP subfamily were identified in Ensembl Release 98. These were manually validated using information on gene synteny and completeness and updated with information from Ensembl Release 100.
Figure 3. Gene synteny suggests that tandem CPO duplicates were formed through unequal crossing over. Gene synteny information was collected from Ensembl. (a) Aebp1, CPZ, and cpxm1 gene paralogs were found on different chromosomes within large blocks of common genes, suggesting a largescale duplication event. (b) CPO gene paralogs were always found in tandem, suggesting unequal crossing-over errors. (c) CPO gene paralogs in Xenopus tropicalis were found within a gamma crystallin gene cluster and just upstream of a transposase-like gene.
Figure 4. Gene size may contribute to rate of gene duplication or duplicate maintenance. The sizes of the indicated genes from 188 species were obtained from Ensembl (Release 98). An independent sample t test was performed comparing all frequently duplicated genes (red) to all others (white; p = 1.59E−37).
Figure 5. Indicators of gene function suggest changes in metallocarboxypeptidase paralog activity and specificity, yet purifying selection to maintain function. Predicted cDNA and amino acid sequences were curated for all duplicated members of the A/B subfamily of metallocarboxypeptidases found in Ensembl. (a, b) Predicted proteins were classified as active enzymes, pseudoenzymes (containing substitutions at active site residues), or pseudogenes (containing large deletions or other deleterious structural mutations). (c, d) Substrate specificity for each predicted protein was predicted based on the identity of the bovine CPA1 residue 255 equivalent. Hydrophobic = hydrophobic residue 255; acidic = basic residue 255; basic = acidic residue 255; polar = polar residue 255. (e, f) The predicted coding sequences for each paralog pair were used in a codon-based test of purifying selection, where greater Ds–dN indicates greater probability of purifying selection. The variance of the difference of synonymous and nonsynonymous substitutions per site was computed using the analytical method. Analyses were conducted using the Nei–Gojobori method in MEGA7. (g) The probability of rejecting the null hypothesis of strict-neutrality (dN = dS) in favor of the alternative hypothesis (dN < dS, purifying selection) is shown. A t-test was used to compare CPO paralogs with all others.
Figure 6. Xenopus tropicalis CPO orthologs are expressed and processed by an endopeptidase. (a) HEK293T cells were transfected with plasmids encoding the four HA-tagged X.t. CPO orthologs, or an empty plasmid (−). Cell lysates (equal amounts of protein) were resolved by SDS-PAGE and western blotted with an anti-HA antibody. The nitrocellulose membrane was also stained with Ponceau S as a loading control. (b) The distribution of HA-tagged X.t. CPO orthologs (green, HA antibody) was analyzed in transfected HEK293T cells by immunocytochemistry and compared with the distribution of transfected human CPO (red, CPO antibody). (c) The four X.t. CPO orthologs were expressed in Sf9 cells using recombinant baculoviruses. Cells were infected with wild-type virus (wtv) as a control. One percent of each cell lysate, or 0.06% of each collected medium, was resolved by SDS-PAGE and western blotted using an HA antibody. (d) Sf9 conditioned media (containing cpo.1, 2, 3, or 4, or wild-type virus (W)) and the same media incubated with 2.5 µg/ml trypsin (T) for 5 min at room temperature were resolved by SDS-PAGE and western blotted with an HA antibody. The membrane was stained with Ponceau S as a loading control.
Figure 7. Xenopus tropicalis CPO orthologs exhibit different substrate preferences. (a) One hundred microliters of each trypsinized media was incubated with 900 µl of 0.5 mM substrate (FA-EE, FA-FA, FA-FF, pH 7.5) at room temperature. Change in absorbance at 340 nm was measured over time and the rate of reaction shown as the change in absorbance (milli-absorbance-units) per minute. n = 3–6. Error bars indicate standard deviation. *p < 0.05, comparing to the corresponding WTV dataset, as determined by ANOVA and Tukey–Kramer post-hoc analysis. (b) Each Xenopus tropicalis CPO paralog was modeled with AlphaFold2 and aligned in Pymol with X-ray crystal structures for Bos taurus CPA (3CPA) and Homo sapiens CPO (5MRV, chain a). All images show the zinc cofactor from Hs CPO as a gray sphere, the zinc cofactor from Bt CPA as a yellow sphere (largely superimposed by the gray sphere) and the Gly-Tyr dipeptide bound to the active site of Bt CPA as a yellow stick model. Key active site residues from each structure are indicated. Cavity surfaces, as viewed from the inside of the protein and with the prodomains removed, are shown in dark grays, while the protein outer surface is shown with white carbons, red oxygens, and blue nitrogens. No substrate binding pocket is shown for Bt CPA, as the pocket is filled with the Gly-Tyr and so not rendered as a surface.
Ahmed,
Transposable elements are a significant contributor to tandem repeats in the human genome.
2012, Pubmed
Ahmed,
Transposable elements are a significant contributor to tandem repeats in the human genome.
2012,
Pubmed
Almagro Armenteros,
SignalP 5.0 improves signal peptide predictions using deep neural networks.
2019,
Pubmed
Avilés,
Advances in metallo-procarboxypeptidases. Emerging details on the inhibition mechanism and on the activation process.
1993,
Pubmed
Baker,
Gene duplication, tissue-specific gene expression and sexual conflict in stalk-eyed flies (Diopsidae).
2012,
Pubmed
Betancur-R,
Phylogenetic classification of bony fishes.
2017,
Pubmed
Blanc,
Functional divergence of duplicated genes formed by polyploidy during Arabidopsis evolution.
2004,
Pubmed
Bratlie,
Gene duplications in prokaryotes can be associated with environmental adaptation.
2010,
Pubmed
Burke,
Carboxypeptidase O is a lipid droplet-associated enzyme able to cleave both acidic and polar C-terminal amino acids.
2018,
Pubmed
Clark,
Whole-Genome Duplication and Plant Macroevolution.
2018,
Pubmed
Conant,
Turning a hobby into a job: how duplicated genes find new functions.
2008,
Pubmed
Copley,
Evolution of new enzymes by gene duplication and divergence.
2020,
Pubmed
Deng,
Evolution of an antifreeze protein by neofunctionalization under escape from adaptive conflict.
2010,
Pubmed
Duckert,
Prediction of proprotein convertase cleavage sites.
2004,
Pubmed
Freeling,
Bias in plant gene content following different sorts of duplication: tandem, whole-genome, segmental, or by transposition.
2009,
Pubmed
Fricker,
Comparison of a carboxypeptidase E-like enzyme in human, bovine, mouse, Xenopus, shark and Aplysia neural tissue.
1988,
Pubmed
,
Xenbase
Garcia-Guerrero,
Crystal structure and mechanism of human carboxypeptidase O: Insights into its specific activity for acidic residues.
2018,
Pubmed
Glasauer,
Whole-genome duplication in teleost fishes and its evolutionary consequences.
2014,
Pubmed
Gomis-Rüth,
Structure and mechanism of metallocarboxypeptidases.
2008,
Pubmed
Grabundzija,
A Helitron transposon reconstructed from bats reveals a novel mechanism of genome shuffling in eukaryotes.
2016,
Pubmed
Greene,
Regulation of carboxypeptidase E. Effect of pH, temperature and Co2+ on kinetic parameters of substrate hydrolysis.
1992,
Pubmed
Grishkevich,
Gene length and expression level shape genomic novelties.
2014,
Pubmed
Guschanski,
The evolution of duplicate gene expression in mammalian organs.
2017,
Pubmed
Hancks,
Active human retrotransposons: variation and disease.
2012,
Pubmed
Huson,
Dendroscope 3: an interactive tool for rooted phylogenetic trees and networks.
2012,
Pubmed
Huxley-Jones,
On the origins of the extracellular matrix in vertebrates.
2007,
Pubmed
Ith,
Aortic carboxypeptidase-like protein is expressed in collagen-rich tissues during mouse embryonic development.
2005,
Pubmed
Kalinina,
A novel subfamily of mouse cytosolic carboxypeptidases.
2007,
Pubmed
Kim,
Carboxypeptidase X-1 (CPX-1) is a secreted collagen-binding glycoprotein.
2015,
Pubmed
Kloareg,
Role and Evolution of the Extracellular Matrix in the Acquisition of Complex Multicellularity in Eukaryotes: A Macroalgal Perspective.
2021,
Pubmed
Kono,
Tandem Duplicate Genes in Maize Are Abundant and Date to Two Distinct Periods of Time.
2018,
Pubmed
Kumar,
Jump around: transposons in and out of the laboratory.
2020,
Pubmed
Layne,
Impaired abdominal wall development and deficient wound healing in mice lacking aortic carboxypeptidase-like protein.
2001,
Pubmed
Lei,
Identification of mouse CPX-1, a novel member of the metallocarboxypeptidase gene family with highest similarity to CPX-2.
1999,
Pubmed
Lezin,
A one-step miniprep for the isolation of plasmid DNA and lambda phage particles.
2011,
Pubmed
Linardopoulou,
Human subtelomeres are hot spots of interchromosomal recombination and segmental duplication.
2005,
Pubmed
Lyons,
Substrate specificity of human carboxypeptidase A6.
2010,
Pubmed
Lyons,
Carboxypeptidase O is a glycosylphosphatidylinositol-anchored intestinal peptidase with acidic amino acid specificity.
2011,
Pubmed
Lyons,
Modeling and functional analysis of AEBP1, a transcriptional repressor.
2006,
Pubmed
Marques,
Evidence for conserved post-transcriptional roles of unitary pseudogenes and for frequent bifunctionality of mRNAs.
2012,
Pubmed
Minh,
IQ-TREE 2: New Models and Efficient Methods for Phylogenetic Inference in the Genomic Era.
2020,
Pubmed
Novikova,
Carboxypeptidase Z is present in the regulated secretory pathway and extracellular matrix in cultured cells and in human tissues.
2000,
Pubmed
Novikova,
Purification and characterization of human metallocarboxypeptidase Z.
1999,
Pubmed
Oh,
Landscape of gene transposition-duplication within the Brassicaceae family.
2019,
Pubmed
Panchy,
Evolution of Gene Duplication in Plants.
2016,
Pubmed
Pierleoni,
PredGPI: a GPI-anchor predictor.
2008,
Pubmed
Rice,
Dosage-sensitive genes in evolution and disease.
2017,
Pubmed
Rizzon,
Striking similarities in the genomic distribution of tandemly arrayed genes in Arabidopsis and rice.
2006,
Pubmed
Rodriguez de la Vega,
Nna1-like proteins are active metallocarboxypeptidases of a new and diverse M14 subfamily.
2007,
Pubmed
Rogowski,
A family of protein-deglutamylating enzymes associated with neurodegeneration.
2010,
Pubmed
Session,
Genome evolution in the allotetraploid frog Xenopus laevis.
2016,
Pubmed
,
Xenbase
Storz,
Gene Duplication and Evolutionary Innovations in Hemoglobin-Oxygen Transport.
2016,
Pubmed
Szostak,
Unequal crossing over in the ribosomal DNA of Saccharomyces cerevisiae.
1980,
Pubmed
Varlamov,
Biosynthesis and packaging of carboxypeptidase D into nascent secretory vesicles in pituitary cell lines.
1999,
Pubmed
Wei,
Identification and characterization of three members of the human metallocarboxypeptidase gene family.
2002,
Pubmed
Woods,
Duplication and retention biases of essential and non-essential genes revealed by systematic knockdown analyses.
2013,
Pubmed
Xin,
Identification of mouse CPX-2, a novel member of the metallocarboxypeptidase gene family: cDNA cloning, mRNA distribution, and protein expression and characterization.
1998,
Pubmed
Zhang,
Generation of tandem direct duplications by reversed-ends transposition of maize ac elements.
2013,
Pubmed