Characterization of the Complete Mitogenome of Mikrogeophagus altispinosus (Cichliformes: Cichlidae) and Phylogenetic Analysis of New World Cichlids
Characterization of the Complete Mitogenome of Mikrogeophagus altispinosus (Cichliformes: Cichlidae) and Phylogenetic Analysis of New World Cichlids
Ye-Ling Lao, Jin-Long Huang, Cheng-He Sun, Xiao-Ying Huang, Ting Wu and Qun Zhang*
Department of Ecology and Institute of Hydrobiology, Jinan University, Guangzhou 510632, China
Ye-Ling Lao and Jin-Long Huang have contributed equally to this work.
ABSTRACT
Following rapid advances in complete mitochondrial genome determination, researchers have published the mitogenomes of many New World cichlids. However, few phylogenetic analyses of New World cichlids have been conducted. In this study, we determined the complete mitogenome of Mikrogeophagus altispinosus. After sequencing with the Illumina HiSeq 4000 platform, SPAdes v3.10.1 was used for assembly, and MITOS2 and MitoFish were used for annotation. We then successfully annotated the mitogenome of M. altispinosus, which has a total length of 16,767 bp. The gene composition and base preferences of M. altispinosus are similar to those of other New World cichlids. Based on the concatenated sequences of 13 protein-coding genes and two rRNAs from the mitogenomes of 37 New World cichlids and one African cichlid, we reconstructed phylogenetic trees using maximum likelihood and Bayesian methods and verified the classification of the target species M. altispinosus. According to our analysis, further studies should focus on the relationships between Amphilophus and Symphysodon. By determining the complete mitogenome of M. altispinosus, this study improves the phylogenetic resolution of New World cichlids. This new resource is highly important for the classification of New World cichlids and provides valuable data for subsequent studies on Cichlidae evolution.
Article Information
Received 13 February 2023
Revised 27 February 2023
Accepted 13 March 2023
Available online 08 June 2023
(early access)
Published 07 October 2024
Authors’ Contribution
YL, JH, CS and QZ designed the study. XH and TW executed experimental work. YL and CS analyzed the data. YL and JH wrote the paper. QZ provided the laboratory equipment. QZ supervised the research.
Key words
Mitochondrial genome, Cichlidae, Bolivian butterfly cichlid, Dwarf butterfly cichlid, mtDNA
DOI: https://dx.doi.org/10.17582/journal.pjz/20230213130221
* Corresponding author: [email protected], [email protected]
0030-9923/2024/0006-2893 $ 9.00/00
Copyright 2024 by the authors. Licensee Zoological Society of Pakistan.
This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Introduction
The first complete mitochondrial genome reported in the literature was that of the most advanced population of vertebrates: human beings (Anderson et al., 1981). Advances in molecular technology have subsequently enabled mitochondrial genome sequencing for diverse species, with data for new taxa regularly being published (Cooper et al., 2001; Macaulay et al., 2005). Fish are the most ancient group of vertebrates, characterized by substantial variation in developmental and evolutionary diversification. In this regard, the phylogenetics and evolutionary development of fish are major areas of research. Most fish species can be identified according to their morphological characteristics. However, mitochondrial DNA analysis has also become an important tool for identifying fish species and populations and for further exploring the origin of fish taxa and hierarchical differentiation with respect to regional water patterns (Stepien and Kocher, 1997).
The Bolivian Butterfly Cichlid or Dwarf Butterfly Cichlid, Mikrogeophagus altispinosus (Haseman, 1911), belongs to the subfamily Geophaginae in the New World cichlid family Cichlidae, order Cichliformes. These aquarium fish, which have a mild temperament and are considered middle-bottom fish, are primarily distributed from Bolivia to northern Trinidad and Tobago (Haseman, 1911; Kullander, 2003; DoNascimiento et al., 2017; Staeck et al., 2022) and are characterized by striking red tails. M. altispinosus have important ecological and ornamental value. This species was first recorded as Crenicara altispinosa by Haseman (1911), then named Mikrogeophagus altispinosa and Papiliochromis altispinosus, and is now designated M. altispinosus (Kullander, 2003; DoNascimiento et al., 2017; Staeck et al., 2022).
The complete mitogenome sequences of many New World cichlids have already been published (Chen et al., 2020; Nam and Rhee, 2022). However, the phylogenetic relationships of new world cichlids according to their mitogenomes remain unclear. In this study, we determined and characterized the complete mitogenome sequence of M. altispinosus. We then evaluated the genetic relationships between M. altispinosus and other New World cichlid species by constructing a molecular phylogenetic tree, which provides a basis for germplasm identification and phylogenetic analyses of the Cichlidae family.
Materials and Methods
Sample collection and ethics statement
The experimental samples were collected from the ornamental fish base in Guangzhou, Guangdong Province, in January 2022 (23° 3′ 57.33″ N, 113° 11′ 34.13″ E). After morphological identification, the pectoral fins were removed, stored in 95% ethanol, transported to the laboratory, and stored in a refrigerator at -20 °C. All experiments were conducted in accordance with Chinese laws, and all experiments were approved by the Animal Ethics Committee of the Department of Ecology of Jinan University and conducted in compliance with relevant animal welfare and protection laws.
DNA extraction, detection, and sequencing
Total DNA was extracted from 25 mg of M. altispinosus fin tissue samples using the Ezup Column Animal Genome DNA Extraction Kit produced by Shanghai Sangong Biological Engineering Co., Ltd. (Shanghai, China), following the instructions provided. After separation by 1% agarose gel electrophoresis, the NanoDrop Lite ultra-micro spectrophotometer (Thermo, USA) was used to detect the quality and concentration of total DNA. Wuhan Banner Technology Co., Ltd. constructed the library and performed sequencing using the Illumina HiSeq 4000 platform to obtain 2×150 bp reads. To ensure the accuracy of morphological identification, COI and Cytb were used for DNA barcoding.
Mitogenome assembly
Trimmomatic v0.39 (Bolger et al., 2014) was used for quality control, and SPAdes v3.10.1 (Bankevich et al., 2012) was used for assembly. Sequences with sufficient coverage depth and long assembly lengths were selected as candidate sequences and compared with those in the NCBI taxonomy database to confirm mitochondrial scaffold sequences. The matched clean reads were then assembled to obtain scaffolds. According to the paired-end reads and overlap relationship, gap closer was used to fill and optimize gaps in the newly assembled results. The parameters were set to default. The reference genome was used to correct the starting position and direction of mitochondrial assembly sequences, and the complete mitochondrial genome was obtained.
Mitogenome annotation and analyses
MITOS2 and MitoFish (Iwasaki et al., 2013) were used to predict protein-coding genes, tRNAs, and rRNAs in the complete mitogenome (Table I). The start and stop codon positions of genes were artificially corrected to obtain highly accurate conservative genomes. DNAStar software (Lasergene, DNAStar, Madison, WI, USA) was used to determine the total length of the mitogenome. MEGA7.0 (Kumar et al., 1994) was used to analyze the base composition, proportion of each part of the genome, and start and end positions of each gene. The asymmetry of the base content of the complete mitogenome was evaluated by AT skew and GC skew (Perna and Kocher, 1995), which were calculated as follows: GC skew = (G−C)/(G+C) and AT skew = (A−T)/(A+T).
Phylogenetic analysis
In total, 38 complete mitogenomes were included in the phylogenetic analysis (Table II), which included the newly obtained mitogenome, 36 complete mitogenome sequences of New World cichlids published in GenBank, and one complete African cichlid mitogenome as an outgroup. As implemented in PhyloSuite v1.2.1 (Zhang et al., 2020), based on 13 protein-coding genes and two rRNA genes, the maximum likelihood method and Bayesian inference method were used for tree construction using IQ-TREE v1.6.8 (Nguyen et al., 2015) and MrBayes v3.2.6 (Huelsenbeck and Ronquist, 2001), respectively. The best-fit partition model (Edge-linked) was selected using the Bayesian information criterion in ModelFinder. Branch support in the maximum likelihood tree was calculated by the self-expanding ultrafast bootstrapping method with 200,000 replicates. Bayesian inference analyses were run with 1,000,000 generations, where the initial 25% of sampled data were discarded as burn-in.
Results and Discussion
Mitogenome features
The length of the mitogenome sequence of M. altispinosus was 16,767 bp, the base composition was 24.65% T, 30.92% C, 27.82% A, and 16.61% G, and the GC content was 47.53%, showing a distinct AT preference,
Table I. Organization of genes in the Mikrogeophagus altispinosus mitogenome with anticodon, direction, position, and length. ‘+’ denotes forward direction and ‘–’ denotes reverse direction.
Name |
Start |
Stop |
Strand |
Length |
Intergenic nucleotides |
Start/stop Codons |
Anticodon |
tRNA-Phe |
1 |
69 |
+ |
69 |
0 |
/ |
GAA |
12S RNA |
70 |
1020 |
+ |
951 |
0 |
/ |
/ |
tRNA-Val |
1021 |
1092 |
+ |
72 |
0 |
/ |
TAC |
16S RNA |
1093 |
2801 |
+ |
1709 |
0 |
/ |
/ |
tRNA-Leu2 |
2802 |
2875 |
+ |
74 |
0 |
/ |
TAA |
ND1 |
2876 |
3850 |
+ |
975 |
2 |
ATG/TAA |
/ |
tRNA-Ile |
3853 |
3922 |
+ |
70 |
-1 |
/ |
GAT |
tRNA-Gln |
3922 |
3992 |
- |
71 |
-1 |
/ |
TTG |
tRNA-Met |
3992 |
4060 |
+ |
69 |
0 |
/ |
CAT |
ND2 |
4061 |
5105 |
+ |
1045 |
0 |
ATG/T |
/ |
tRNA-Trp |
5106 |
5177 |
+ |
72 |
1 |
/ |
TCA |
tRNA-Ala |
5179 |
5247 |
- |
69 |
1 |
/ |
TGC |
tRNA-Asn |
5249 |
5321 |
- |
73 |
34 |
/ |
GTT |
tRNA-Cys |
5356 |
5422 |
- |
67 |
-1 |
/ |
GCA |
tRNA-Tyr |
5422 |
5489 |
- |
68 |
1 |
/ |
GTA |
COI |
5491 |
7050 |
+ |
1560 |
27 |
GTG/TAA |
/ |
tRNA-Ser2 |
7078 |
7149 |
- |
72 |
3 |
/ |
TGA |
tRNA-Asp |
7153 |
7225 |
+ |
73 |
5 |
/ |
GTC |
COII |
7231 |
7921 |
+ |
691 |
0 |
ATG/T |
/ |
tRNA-Lys |
7922 |
7994 |
+ |
73 |
1 |
/ |
TTT |
ATP8 |
7996 |
8163 |
+ |
168 |
-10 |
ATG/TAA |
/ |
ATP6 |
8154 |
8836 |
+ |
683 |
0 |
ATG/TA |
/ |
COIII |
8837 |
9620 |
+ |
784 |
0 |
ATG/T |
/ |
tRNA-Gly |
9621 |
9692 |
+ |
72 |
0 |
/ |
TCC |
ND3 |
9693 |
10041 |
+ |
349 |
0 |
ATG/T |
/ |
tRNA-Arg |
10042 |
10110 |
+ |
69 |
0 |
/ |
TCG |
ND4L |
10111 |
10407 |
+ |
297 |
-7 |
ATG/TAA |
/ |
ND4 |
10401 |
11781 |
+ |
1381 |
0 |
ATG/T |
/ |
tRNA-His |
11782 |
11850 |
+ |
69 |
0 |
/ |
GTG |
tRNA-Ser1 |
11851 |
11917 |
+ |
67 |
8 |
/ |
GCT |
tRNA-Leu1 |
11926 |
11998 |
+ |
73 |
0 |
/ |
TAG |
ND5 |
11999 |
13837 |
+ |
1839 |
-4 |
ATG/TAA |
/ |
ND6 |
13834 |
14355 |
- |
522 |
0 |
ATG/TAG |
/ |
tRNA-Glu |
14356 |
14424 |
- |
69 |
4 |
/ |
TTC |
Cyt b |
14429 |
15569 |
+ |
1141 |
0 |
ATG/T |
/ |
tRNA-Thr |
15570 |
15641 |
+ |
72 |
-1 |
/ |
TGT |
tRNA-Pro |
15641 |
15710 |
- |
70 |
0 |
/ |
TGG |
D-loop |
15711 |
16767 |
+ |
1057 |
0 |
/ |
/ |
Table II. Taxon, GenBank accession number, and base composition information for the available mitogenomes of 38 Cichlidae species included in this study.
Taxon (Species) |
Size (bp) |
AT % |
AT- Skew |
GC- Skew |
GenBank |
New World Cichlids |
|||||
Astronotinae |
|||||
Astronotus ocellatus |
16569 |
55 |
0.049 |
-0.342 |
NC_009058.1 |
Chaetobranchopsis bitaeniatus |
16610 |
58.4 |
0.042 |
-0.351 |
NC_033542.1 |
Cichlasomatinae |
|||||
Aequidens metae |
16541 |
53.6 |
0.037 |
-0.315 |
NC_033544.1 |
Amphilophus amarillo |
16521 |
54.1 |
0.053 |
-0.34 |
KY315559.1 |
Amphilophus citrinellus |
16522 |
54.2 |
0.054 |
-0.34 |
NC_023827.1 |
Andinoacara pulcher |
16513 |
56.8 |
0.011 |
-0.299 |
NC_033547.1 |
Andinoacara rivulatus |
16585 |
56.9 |
-0.019 |
-0.259 |
NC_025671.1 |
Bujurquina mariae |
16540 |
58.8 |
0.004 |
-0.286 |
NC_033543.1 |
Bujurquina oenolaemus |
16532 |
57.5 |
0.012 |
-0.301 |
KX397358.1 |
Cichlasoma dimerus |
16617 |
54.5 |
0.041 |
-0.327 |
NC_033551.1 |
Cryptoheros cutteri |
16528 |
52.9 |
0.04 |
-0.328 |
NC_033552.1 |
Herichthys cyanoguttatus |
16540 |
53.4 |
0.059 |
-0.344 |
NC_033546.1 |
Heros severus |
16577 |
56.9 |
0.03 |
-0.221 |
MT363636.1 |
Hypselecara temporalis |
16544 |
53.9 |
0.021 |
-0.316 |
NC_011168.1 |
Krobia guianensis |
16539 |
54.3 |
0.045 |
-0.324 |
NC_031440.1 |
Nannacara anomala |
16502 |
53.4 |
0.025 |
-0.301 |
NC_031183.1 |
Parachromis managuensis |
16526 |
53.6 |
0.049 |
-0.339 |
NC_026918.1 |
Petenia splendida |
16518 |
53.2 |
0.053 |
-0.338 |
NC_024835.1 |
Pterophyllum altum |
16495 |
54.2 |
0.014 |
-0.325 |
NC_028723.1 |
Pterophyllum scalare |
16491 |
54.2 |
0.016 |
-0.317 |
NC_026535.1 |
Rocio octofasciata |
16539 |
54.4 |
0.041 |
-0.34 |
NC_033548.1 |
Symphysodon aequifasciata |
16545 |
54.9 |
0.049 |
-0.335 |
NC_028182.1 |
Symphysodon discus |
16544 |
54.9 |
0.052 |
-0.337 |
NC_026689.1 |
Symphysodon haraldi |
16543 |
54.9 |
0.051 |
-0.336 |
NC_027965.1 |
Thorichthys aureus |
16530 |
52.1 |
0.042 |
-0.325 |
NC_031182.1 |
Thorichthys meeki |
16527 |
53.2 |
0.052 |
-0.339 |
MZ427899.1 |
Uaru amphiacanthoides |
16549 |
54.4 |
0.044 |
-0.326 |
NC_033550.1 |
Vieja melanura |
16543 |
52.6 |
0.058 |
-0.335 |
NC_023526.1 |
Cichlinae |
|||||
Cichla ocellaris |
16526 |
54.3 |
0.076 |
-0.35 |
NC_030272.1 |
Geophaginae |
|||||
Apistogramma cacatuoides |
16870 |
54.3 |
0.025 |
-0.302 |
KR150874.1 |
Geophagus brasiliensis |
16559 |
54.1 |
0.044 |
-0.319 |
NC_031181.1 |
Geophagus steindachneri |
16594 |
53.8 |
0.063 |
-0.339 |
NC_033545.1 |
Gymnogeophagus balzanii |
16587 |
56 |
0.018 |
-0.306 |
KR150864.1 |
Mikrogeophagus altispinosus |
16767 |
52.4 |
0.06 |
-0.301 |
OP595704 |
Mikrogeophagus ramirezi |
16526 |
55.4 |
0.033 |
-0.294 |
NC_031439.1 |
Taeniacara candidi |
16581 |
57.2 |
-0.005 |
-0.29 |
KR150873.1 |
Retroculinae |
|||||
Retroculus lapidifer |
16537 |
52.8 |
0.058 |
-0.314 |
NC_033549.1 |
African cichlid (outgroup) |
|||||
Pseudocrenilabrinae |
|||||
Tylochromis polylepis |
16976 |
54.5 |
0.041 |
-0.319 |
NC_011171.1 |
similar to the base composition of vertebrate genomes. The M. altispinosus G base content was similar to that of other teleost fishes, indicating a substantial anti-guanine skew (Gong et al., 2017).
Because of differences in selection pressure and natural mutation rates between DNA strands, the distributions of bases and mutations are often uneven (Brown et al., 1982). In the mitogenome of M. altispinosus, except for ND6 and eight tRNA coding genes located on the light strand, the other 26 coding genes were located on the heavy strand, similar to those in the mitogenomes of other fish (Ma et al., 2015; Yu and Kwak, 2015). The length of overlapping fragments in the genome of fish is generally only 7–10 bp, compared with 40–46 bp fragment length in mammals (Broughton et al., 2001; Zhu et al., 2013). In this study, we found that the length of M. altispinosus overlapping fragments was 1–34 bp, with a maximum overlap of 34 bp between tRNA-Asn and tRNA-Cys because of the light-strand replication origin between the two genes and minimum overlapping fragments (1 bp) between tRNA-Trp/tRNA-Ala, tRNA-Ala/tRNA-Asn, tRNA-Tyr/COI, and tRNA-Lys/ATP8. The control region showed substantial variation and a high rate of evolution. In this study, the A+T content (60.08%) was also relatively high in the M. altispinosus control region, which regulates mitochondrial replication and transcription.
According to the start and stop positions, length, and base composition of the 37 genes in the mitogenome of M. altispinosus, the mitogenome characteristics are highly similar to those of M. ramirezi, another species in the same genus. However, there are also differences, for example, the 16S RNA of M. altispinosus was 17 bp longer than that of M. ramirezi. Among the protein-coding genes, the ATP6 of M. altispinosus was 1 bp shorter, the Cytb was 1 bp longer, and the COI was 3 bp longer than those of M. ramirezi.
The protein-coding genes of the complete mitogenome had an identical starting codon in M. altispinosus and M. ramirezi; however, the ATP6 and Cytb of M. ramirezi had the termination codon TAA, in contrast to the incomplete terminator T/TA in M. altispinosus. The 3 end of the post-transcriptional product of the incomplete termination codon is U, the mitochondrial mRNA is polyadenylated after transcription, and the termination codon T finally forms the UAA termination codon (Ojala et al., 1981). Among the 37 New World cichlids mitogenomes published to date, the AT% was greater than 50% (range: 52.1%–58.8%), and the length range was 16,491–16,870 bp. The GC skew showed evident negative values, and the AT skew was positive, except in the genomes of Andinoacara rivulatus and Taeniacara candidi. These characteristics were similar to those reported previously in the mitogenomes of Cichlidae (Chen et al., 2020; Nam and Rhee, 2022).
Phylogenetic analysis
To understand the evolutionary relationships of New World cichlids, maximum likelihood (Fig. 1) and Bayesian inference (Fig. 2) trees were constructed based on 13 protein-coding genes and two rRNAs from 38 species. Phylogenetic trees constructed using these two methods revealed the same topological structure, except for the location of Chaetobranchopsis bitaeniatus. The target species M. altispinosus and M. ramirezi were clustered with high support (bootstrap value of 100% and Bayesian posterior probability value of 1.0), and the monophyly of Geophaginae was well supported. All species in Cichlasomatinae, except Heros severus, were closely clustered. Among the eight multi-species genera (i.e., those including two or more species), we observed consistent classification and morphological results for seven genera, Amphilophus, Andinoacara, Bujurquina, Pterophyllum, Symphysodon, Thorichthys, and Mikrogeophagus; only two Geophagus species failed to form a branch. The two Astronotinae species also failed to form a single branch. At present, few complete mitogenomes are available for Astronotinae, Cichlinae, and Retroculinae, indicating that more research is required.
Notably, the tree lengths of Amphilophus and Symphysodon were very short or nearly zero in both phylogenetic trees. Comparing the complete mitogenome sequences of Amphilophus amarillo and A. citrinellus revealed only four substitutions. The complete mitogenome sequences of Symphysodon aequifasciata, S. discus, and S. haraldi were also compared, which revealed differences between S. aequifasciatus and the other two species, with 243 variant sites as well as 41 variant sites between S. discus and S. haraldi. We propose at least three reasons for this result: morphological identification error, co-evolution, or interspecific hybridization. We expect that the novel mitogenome sequenced in this study will be useful for detailed analyses of M. altispinosus genetics as well as further phylogenetic studies, particularly as more data become available.
Acknowledgments
Authors are grateful to the reviewer for the constructive criticisms and valuable comments.
Funding
This work was supported by the National Key R&D Program of China (Grant number 2018YFD0900802) and the Fishery Resources Survey of Guangxi Zhuang Autonomous Region (GXZC2022-G3-001062-ZHZB).
IRB approval and ethical statement
All experiments were approved by the Animal Ethics Committee of the Department of Ecology of Jinan University and conducted in compliance with relevant animal welfare and protection laws.
Statement of conflict of interest
The authors have declared no conflict of interest.
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