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  1. That have been aligned so that homologousresidues are arranged in columns as much as possible. The sequences have different lengths, which means that gaps must be used in some positions to achieve the alignment. If the sequences were all the same length, the gaps would not be needed.Such as structure prediction or to demonstrate sequence similarity within a family of sequences.Phylogenetic analyses. Rates or patterns of change in sequences

  2. How to carry out an alignment, either manually or using a computer program. Any phylogeny inference based on molecular data begins by comparing the homologous residues (i.e., those that descend from a common ancestral residue)

  3. Difficult to find this ideal alignment first, there may be repeats in one or all members of the sequence family; with duplications of entire protein domains,With small-grain repeats, such as those involving single nucleotides or with microsatellite sequences, the problem is worse.

  4. One alignment of sequences is better than any other, except cosmetically.Fortunately, it often makes no difference phylogenetically if these regions are simply ignored for phylogenetic analysis.Fortunately, they tend to be localized to nonprotein coding or hypervariable regions; these will be almost impossible to align unambiguously and should be treated with caution. In amino-acid sequences, such localized repeats of residues are unusual, whereas large-scale repeats of entire protein domains are common.

  5. If the sequences in a data set accumulate few substitutions over time, they will remain similar and will be easy to align.Sequence identity, is the number of identical residues in an alignment divided by the number of aligned positions, excluding any positions with a gap.

  6. When examining the nature of these changes, two patterns emerge. First, the identities and differences are not evenly distributed along the sequence. Blocks of alignment with between 5 and 20 residues will have more identities and more similar amino acids than elsewhere.Conserved secondary-structure elements of α-helixes and β-strands in the proteins,One benefit of this block-like similarity is that there will be regions of alignment that are clear and unambiguous and that which most computer programs can find easily, even between distantly related sequences.

  7. The second observed pattern is that most pairs of aligned, but nonidentical, residues are biochemically similar (i.e., their side chains are similar)conserved secondary-structure active sites or ligand-binding domains.Polarity/hydrophobicity

  8. The PAM matrixes were derived from the original empirical data using a sophisticated evolutionary model,Less weight is given to residues that change easily during evolution, such as Alanine or Serine, and more weight is given to those that change less frequently, such as Tryptophan.

  9. The alignment problem is finding the arrangement of amino acids resulting in the highest score,hidden markov models (HMMs), which use probabilities rather than scores; these methods use a related concept of amino-acid similarity.

  10. In alignments, they appear as gaps inserted in sequences to maximize an alignment score.Where l is the length of the gap, g is a gap-opening penalty (charged once per gap), and h is a gap-extension penalty (charged once per hyphen in a gap). These penalties are often referred to as affine gap penalties. In practice, the values of g and h are chosen arbitrarily, and there is no reason to believe that gaps evolve as simply as the formula suggests, significantly, the alignment with the highest alignment score may or may not be the correct alignment biologically.

  11. Exaggerated claims have been made about how effective some methods are or why others should never be used. The user-friendliness of the software and its availability are important secondary considerations, but it is the quality of the alignments that matter most.BaliBase (Thompson et al., 1999b), which is 141 alignments from five different types of alignment situations: (1) equidistant (small sets of phylogenetically equidistant sequences); (2) orphan (as for Type 1 but with one distant member of the family); (3) two families (two sets of related sequences distantly related to each other); (4) long insertions (one or more sequences have a long insertion); and (5) long deletions.

  12. Probably the easiest and certainly the most common way to look for regions with high similarity scores among nucleotide or amino-acid sequences is to obtain a dot-matrix representation, or dot plot.

  13. For two sequences, dynamic programming can find the best alignment buy giving scores for all possible pairs of aligned residues and GPs.The approach can easily be generalized to more than two sequences.The weighted sum of pairs (WSP) objective function:Σ ΣWijDijFor any multiple alignment, a score between each pair of sequences (Dij) is calculated. Then, the WSP function is simply the sum of all of these scores, 1 for each possible pair of sequences. There is an extra term Wij for each pair, which is a weight; by default, it will always be equal to 1,

  14. The complexity is O(NM), where M is the number of sequences and N is the sequence length. This quickly becomes impossible to compute for more than four sequences of even modest lengths.The MSA program of Lipman et al. (1989) it used a so-called branch-and-bound technique to eliminate many unnecessary calculations and make it possible to compute the WSP function for five to eight sequences.In tests with BaliBase, this program performed extremely well but it cannot handle all test cases. The FastMSA program, a highly optimized version of MSA, is faster and uses less memory, but is still limited to small data sets.

  15. The SAGA program is based on the WSP objective function but uses a genetic algorithm rather than dynamic programming to find the best alignment.Using a process of selection and crossing to find the best alignment.The advantage of SAGA, however, is its ability to deliver good alignments for more than eight sequences; the disadvantage is that it is still relatively slow, perhaps taking many hours of computing to deliver a good alignment for 20 to 30 sequences. The program also must be run several times because results can differ between runs.

  16. The DCA (Stoye et al., 1997) and PRRP (Gotoh, 1996) programs also compute alignments according to the WSP scoring function. The former program finds sections of alignment that, when joined together head to tail, give the best alignment.PRRP uses an iterative scheme to gradually work toward the optimal alignment. At each cycle of iteration, the sequences are split into two groups (randomly). Within each group, the sequences are kept in fixed alignment, and are then aligned to each other using dynamic programming.The program is slow with more than 20 sequences, but it is faster than SAGA.The DIALIGN method of Morgenstern (1999) is based on finding sections of local multiple alignment in a set of sequences; that is, sections similar across all sequences, but relatively short.

  17. It is clear that multiple alignments are useful for phylogenetic relationships in a set of sequences were known, this information could be used to help generate an alignment.A simple shortcut is to create an approximate tree of the sequences and use it to make a multiple alignment; this approach was first suggested by Hogeweg and Hesper (1984)

  18. A similar tree can be generated quickly by making all possible pairwise alignments between all the sequences and calculating a distance .Such distances are used to make the tree with one of the widely available distance methods, such as the Neighbor-Joining (NJ) method of Saitou and Nei (1987)next, the alignment is gradually built up by following the branching order in the tree. The two closest sequences are aligned first, using dynamic programming with GPs and a weight matrix. For further alignment, the two sequences are treated as one, such that any gaps created between the two cannot be moved. Again, the tow closest remaining sequences or prealigned groups of sequences are aligned to each other.The process is repeated until all the sequences are aligned. Once the initial tree is generated, the multiple alignment can be accomplished with only N-1 separate alignments for N sequences. This process is fast enough to allow the alignment of many hundreds of sequences.

  19. The most commonly used software for this typw of alignment is ClustalW (Thompson et al., 1994) and ClustalX.These programs are identical in terms of alignment method, but offer either a simple text-based interface (ClustalW) suitable for high-throughput tasks or a graphical interface (ClustalX). ClustalW can take a set of input sequences and automatically perform the entire progressive alignment procedure. The sequences are aligned in pairs to generate a distance matrix that can be used to make a simple initial tree of the sequences. This guide tree is stored in a file The multiple alignment is finally carried out using the progressive approach, described previously.

  20. First, sequences are downweighted according to how closely related they are to other sequences.Second, the weight matrix used for protein alignments varies, depending on how closely related are the next two sequences or sets of sequences.ClustalW uses a series of four matrixes chosen from either the BLOSUM or PAM series.GPs are lowered in runs of hydrophilic residues (likely loops) or at positions where there are already many gaps. They are also lowered near some residues, such as Glycine, which are empirically known to be common near gaps. These and other parameters can be set by the user before each alignment.

  21. Progressive alignment is fast and simple but it does have one obvious drawback: a local minimum problem. Any alignment errors that occur during the early alignment steps cannot be corrected later as more data are added. This may be due to an incorrect topology in the guide tree, but it is more likely due to simple errors in the early alignments.An effective way to overcome this problem is to use the recently developed T-Coffee method.

  22. The method is based on finding the multiple alignment that is most consistent with a set of pairwise alignments between the sequences.These are processed to find the aligned pairs of residues in the initial data set that are most consistent across different alignments. This information then is used to compile data on which residues are most likely to align in which sequences. The final stage is to create the multiple alignment using normal progressive alignment, The disadvantages of T-Coffee over ClustalW are the extra computer time required for alignment and the lack of functionality in the software. The formre is of concern for only 50 sequences; the latter will change over time as new software is developed.

  23. HMMs, which are based on probabilities of residue substitution and gap insertion and deletion. HMMs have been shown to be extremely useful in locating introns and exons or predicting promoters in DNA sequences. HMMs are also useful for summarizing the diversity of information in an existing alignment of sequences and predicting whether new sequences belong to the family.

  24. In the case of protein-coding genes, the alignment can be accomplished based on the nucleotide or the amino-acid sequences.If the sequences are distantly related, analysis can be by either amino-acid or nucleotide differences.Amino-acid sequence alignments are easier to carry out and less ambiguous than nucleotide alignments.A typical approach is to carry out the alignment at the amino-acid level and use it to generate a corresponding nucleotide sequence alignment, which can then be analyzed as usual. Numerous computer programs are available; for example, PROTAL2DNA by Catherine Letondal (http://bioweb.pasteur.fr/seqanal/interfaces/protald2dna.html) or DAMBE (discussed later in this section).

  25. If the sequence code is for structural RNATypically, there are regions of clear nucleotide identity interspersed by regions that are free to change rapidlythere may be no clear alignment in these regions that can be chosen over any others. Excluding these regions from further analysis should be seriously considered.Fortunately, there are usually enough clearly conserved blocks of alignment to make a phylogenetic analysis possible.If the nucleotide sequences are noncoding, then alignment may be difficult once the sequences diverge beyond a certain level.

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