Molecular phylogenetics

Molecular phylogenetics (/məˈlɛkjʊlər ˌfaɪloʊdʒəˈnɛtɪks, mɒ-, moʊ-/^[1]^[2]) is the branch of phylogeny that analyzes genetic, hereditary molecular differences, predominantly in DNA sequences, to gain information on an organism's evolutionary relationships. From these analyses, it is possible to determine the processes by which diversity among species has been achieved. The result of a molecular phylogenetic analysis is expressed in a phylogenetic tree. Molecular phylogenetics is one aspect of molecular systematics, a broader term that also includes the use of molecular data in taxonomy and biogeography.^[3]^[4]^[5]

Molecular phylogenetics and molecular evolution correlate. Molecular evolution is the process of selective changes (mutations) at a molecular level (genes, proteins, etc.) throughout various branches in the tree of life (evolution). Molecular phylogenetics makes inferences of the evolutionary relationships that arise due to molecular evolution and results in the construction of a phylogenetic tree.^[6]

History

The theoretical frameworks for molecular systematics were laid in the 1960s in the works of Emile Zuckerkandl, Emanuel Margoliash, Linus Pauling, and Walter M. Fitch.^[7] Applications of molecular systematics were pioneered by Charles G. Sibley (birds), Herbert C. Dessauer (herpetology), and Morris Goodman (primates), followed by Allan C. Wilson, Robert K. Selander, and John C. Avise (who studied various groups). Work with protein electrophoresis began around 1956. Although the results were not quantitative and did not initially improve on morphological classification, they provided tantalizing hints that long-held notions of the classifications of birds, for example, needed substantial revision. In the period of 1974–1986, DNA–DNA hybridization was the dominant technique used to measure genetic difference.^[8]

Theoretical background

Early attempts at molecular systematics were also termed chemotaxonomy and made use of proteins, enzymes, carbohydrates, and other molecules that were separated and characterized using techniques such as chromatography. These have been replaced in recent times largely by DNA sequencing, which produces the exact sequences of nucleotides or bases in either DNA or RNA segments extracted using different techniques. In general, these are considered superior for evolutionary studies, since the actions of evolution are ultimately reflected in the genetic sequences. At present, it is still a long and expensive process to sequence the entire DNA of an organism (its genome). However, it is quite feasible to determine the sequence of a defined area of a particular chromosome. Typical molecular systematic analyses require the sequencing of around 1000 base pairs. At any location within such a sequence, the bases found in a given position may vary between organisms. The particular sequence found in a given organism is referred to as its haplotype. In principle, since there are four base types, with 1000 base pairs, we could have 4¹⁰⁰⁰ distinct haplotypes. However, for organisms within a particular species or in a group of related species, it has been found empirically that only a minority of sites show any variation at all, and most of the variations that are found are correlated, so that the number of distinct haplotypes that are found is relatively small.^[9]

In a molecular systematic analysis, the haplotypes are determined for a defined area of genetic material; a substantial sample of individuals of the target species or other taxon is used; however, many current studies are based on single individuals. Haplotypes of individuals of closely related, yet different, taxa are also determined. Finally, haplotypes from a smaller number of individuals from a definitely different taxon are determined: these are referred to as an outgroup. The base sequences for the haplotypes are then compared. In the simplest case, the difference between two haplotypes is assessed by counting the number of locations where they have different bases: this is referred to as the number of substitutions (other kinds of differences between haplotypes can also occur, for example, the insertion of a section of nucleic acid in one haplotype that is not present in another). The difference between organisms is usually re-expressed as a percentage divergence, by dividing the number of substitutions by the number of base pairs analysed: the hope is that this measure will be independent of the location and length of the section of DNA that is sequenced.

An older and superseded approach was to determine the divergences between the genotypes of individuals by DNA–DNA hybridization. The advantage claimed for using hybridization rather than gene sequencing was that it was based on the entire genotype, rather than on particular sections of DNA. Modern sequence comparison techniques overcome this objection by the use of multiple sequences.

Once the divergences between all pairs of samples have been determined, the resulting triangular matrix of differences is submitted to some form of statistical cluster analysis, and the resulting dendrogram is examined in order to see whether the samples cluster in the way that would be expected from current ideas about the taxonomy of the group. Any group of haplotypes that are all more similar to one another than any of them is to any other haplotype may be said to constitute a clade, which may be visually represented as the figure displayed on the right demonstrates. Statistical techniques such as bootstrapping and jackknifing help in providing reliability estimates for the positions of haplotypes within the evolutionary trees.

Techniques and applications

Every living organism contains deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and proteins. In general, closely related organisms have a high degree of similarity in the molecular structure of these substances, while the molecules of organisms distantly related often show a pattern of dissimilarity. Conserved sequences, such as mitochondrial DNA, are expected to accumulate mutations over time, and assuming a constant rate of mutation, provide a molecular clock for dating divergence. Molecular phylogeny uses such data to build a "relationship tree" that shows the probable evolution of various organisms. With the invention of Sanger sequencing in 1977, it became possible to isolate and identify these molecular structures.^[10]^[11] High-throughput sequencing may also be used to obtain the transcriptome of an organism, allowing inference of phylogenetic relationships using transcriptomic data.

The most common approach is the comparison of homologous sequences for genes using sequence alignment techniques to identify similarity. Another application of molecular phylogeny is in DNA barcoding, wherein the species of an individual organism is identified using small sections of mitochondrial DNA or chloroplast DNA. Another application of the techniques that make this possible can be seen in the very limited field of human genetics, such as the ever-more-popular use of genetic testing to determine a child's paternity, as well as the emergence of a new branch of criminal forensics focused on evidence known as genetic fingerprinting.

Molecular phylogenetic analysis

There are several methods available for performing a molecular phylogenetic analysis. One method, including a comprehensive step-by-step protocol on constructing a phylogenetic tree, including DNA/Amino Acid contiguous sequence assembly, multiple sequence alignment, model-test (testing best-fitting substitution models), and phylogeny reconstruction using Maximum Likelihood and Bayesian Inference, is available at Nature Protocol.^[12]

Another molecular phylogenetic analysis technique has been described by Pevsner and shall be summarized in the sentences to follow (Pevsner, 2015). A phylogenetic analysis typically consists of five major steps. The first stage comprises sequence acquisition. The following step consists of performing a multiple sequence alignment, which is the fundamental basis of constructing a phylogenetic tree. The third stage includes different models of DNA and amino acid substitution. Several models of substitution exist. A few examples include Hamming distance, the Jukes and Cantor one-parameter model, and the Kimura two-parameter model (see Models of DNA evolution). The fourth stage consists of various methods of tree building, including distance-based and character-based methods. The normalized Hamming distance and the Jukes-Cantor correction formulas provide the degree of divergence and the probability that a nucleotide changes to another, respectively. Common tree-building methods include unweighted pair group method using arithmetic mean (UPGMA) and Neighbor joining, which are distance-based methods, Maximum parsimony, which is a character-based method, and Maximum likelihood estimation and Bayesian inference, which are character-based/model-based methods. UPGMA is a simple method; however, it is less accurate than the neighbor-joining approach. Finally, the last step comprises evaluating the trees. This assessment of accuracy is composed of consistency, efficiency, and robustness.^[13]

Five Stages of Molecular Phylogenetic Analysis

MEGA (molecular evolutionary genetics analysis) is an analysis software that is user-friendly and free to download and use. This software is capable of analyzing both distance-based and character-based tree methodologies. MEGA also contains several options one may choose to utilize, such as heuristic approaches and bootstrapping. Bootstrapping is an approach that is commonly used to measure the robustness of topology in a phylogenetic tree, which demonstrates the percentage each clade is supported after numerous replicates. In general, a value greater than 70% is considered significant. The flow chart displayed on the right visually demonstrates the order of the five stages of Pevsner's molecular phylogenetic analysis technique that have been described.^[13]

Applications of Molecular Phylogenetic Analysis

Molecular phylogenetic analyses have broad applications across multiple biological disciplines, including genomics, evolutionary biology, epidemiology, and biodiversity research. By comparing DNA, RNA, or protein sequences, researchers can reconstruct evolutionary relationships, investigate patterns of adaptation and diversification, and infer the history of genes and species. These approaches are used to address both fundamental and applied biological questions.^[14]

Systematics and species classification

Molecular phylogenetic analysis has transformed biological systematics by providing an objective framework for classifying organisms based on genetic relationships rather than solely on morphological characteristics. By comparing homologous DNA or protein sequences, researchers can reconstruct evolutionary relationships and refine taxonomic classifications to better reflect common ancestry. Phylogenetic evidence has led to the reclassification of numerous taxa, clarification of previously ambiguous relationships, and identification of cryptic species that are morphologically similar but genetically distinct. Molecular data have also helped resolve deep evolutionary relationships that were difficult to infer using morphology alone.^[15]

For example, traditional classifications based on morphology once grouped all diurnal birds of prey together in Falconiformes, which look superficially similar to other raptors or even to large Anseriformes (waterfowl). However, molecular phylogenetic studies have demonstrated that falcons (family Falconidae) are not most closely related to hawks and eagles (order Accipitriformes) as previously thought. Instead, genome-wide analyses place falcons within the clade Australaves, making them more closely related to passerines (songbirds) and parrots than to hawks and eagles. This case illustrates how molecular data can overturn long-held morphological classifications and provide a more accurate picture of evolutionary relationships.^[16]

As a result, molecular phylogenetics plays a central role in modern systematic biology and evolutionary taxonomy, helping to refine classifications, identify cryptic species, and clarify deep divergences that morphology alone cannot resolve.^[17]

Genomics and Gene Family Evolution

In Genomics and molecular biology, molecular phylogenetic studies are widely used to investigate the evolutionary history of genes and gene families. These analyses help to identify orthologous and paralogous relationships, distinguish speciation from gene duplication events and clarify the evolutionary origins of gene families. Phylogenetic approaches can also trace independent loss events and differentiate them from duplications or other evolutionary processes, revealing how specific genes may be lost or modified in different lineages and how these changes contribute to functional diversification. For example, MDA5 gene has been independently lost in several unrelated vertebrate lineages, including mammals and chickens (Galliformes), and has been disrupted in storks (Ciconiiformes) and rallids (Gruiformes).^[18]

Evolutionary Biology and Trait Evolution

Molecular Phylogenetic analyses are widely used in the field of evolutionary biology to address various evolutionary questions, such as how traits evolve across species. One important application is the study of convergent evolution, where similar functional traits independently emerge in distantly related lineages as a result of comparable selective pressures.^[19] To investigate patterns of convergence across species, tanglegrams are often used. These are visual tools for comparing two phylogenetic trees, usually a species tree and a gene tree. By examining concordance and discordance between the trees, researchers can detect instances where similar traits or amino acid changes have independently evolved in distantly related lineages. Comparative analysis of gene or protein sequences further reveals specific convergent changes across species. For example, phylogenetic studies have identified convergent amino acid substitutions in genes involved in immunity, such as TLRs, highlighting how natural selection shapes protein evolution across distantly related species.^[20]

Infectious Disease and Epidemiology

Molecular phylogenetic analysis plays a key role in infectious disease research by reconstructing the evolutionary relationships among pathogens and their hosts. For example, phylogenetic studies have shown that waterfowl, particularly dabbling ducks(Anas spp.), are the major reservoirs of circulating influenza A virus strains and share the recent common viral ancestor with mammalian influenza viruses.^[21] Phylogenetic trees and comparative analysis help to compare viral genome sequences across different host species and allow researchers to infer transmission pathways, identify ancestral viral lineages and virus evolution and adaptation to new hosts. Phylogenetic analyses have also demonstrated that key components of innate immune systems, such as Toll-like receptors, RIG-I-like receptors, and NOD-like receptors, are conserved across vertebrates despite their deep evolutionary divergence.^[22]^[23]^[24] The conservation of these immune genes across distantly related lineages, revealed through phylogenetic analysis, highlights their shared evolutionary origin.

Biodiversity and Conservation Biology

Molecular phylogenetics plays a key role in biodiversity research by enabling species identification, detecting cryptic species, reconstructing evolutionary relationships, and informing conservation planning. These analyses help identify evolutionarily distinct lineages and prioritise populations for protection, while also revealing processes that can threaten genetic integrity. For example, introgression, the transfer of genetic material between species through hybridisation, can disrupt native populations, particularly when non-native species are introduced by humans. Phylogenetic and genome-wide analyses have demonstrated this in the case of the native red-legged partridge (Alectoris rufa) and the introduced chukar partridge (Alectoris chukar), where hybridisation altered the genetic structure of native populations. Such findings illustrate how molecular markers can be used not only to understand biodiversity but also to monitor and restore genetic integrity in managed wildlife populations.^[25]

Limitations

Molecular systematics is an essentially cladistic approach: it assumes that classification must correspond to phylogenetic descent, and that all valid taxa must be monophyletic. This is a limitation when attempting to determine the optimal tree(s), which often involves bisecting and reconnecting portions of the phylogenetic tree(s).

The recent discovery of extensive horizontal gene transfer among organisms provides a significant complication to molecular systematics, indicating that different genes within the same organism can have different phylogenies. HGTs can be detected and excluded using a number of phylogenetic methods (see Inferring horizontal gene transfer § Explicit phylogenetic methods).

In addition, molecular phylogenies are sensitive to the assumptions and models that go into making them. Firstly, sequences must be aligned; then, issues such as long-branch attraction, saturation, and taxon sampling problems must be addressed. This means that strikingly different results can be obtained by applying different models to the same dataset.^[26]^[27] The tree-building method also brings with it specific assumptions about tree topology, evolution speeds, and sampling. The simplistic UPGMA assumes a rooted tree and a uniform molecular clock, both of which can be incorrect.^[13]

The low resolution power of single genes have been overcome using multigene phylogenies, though the issue of HGT still merits careful algorithmic design.^[28]