File Coverage

Bio/SeqFeature/Gene/Transcript.pm

Criterion	Covered	Total	%
statement	164	222	73.8
branch	48	86	55.8
condition	26	44	59.0
subroutine	24	32	75.0
pod	20	23	86.9
total	282	407	69.2

line	stmt	bran	cond	sub	pod	time	code
1							#
2							# BioPerl module for Bio::SeqFeature::Gene::Transcript
3							#
4							# Please direct questions and support issues to
5							#
6							# Cared for by Hilmar Lapp
7							#
8							# Copyright Hilmar Lapp
9							#
10							# You may distribute this module under the same terms as perl itself
11
12							# POD documentation - main docs before the code
13
14							=head1 NAME
15
16							Bio::SeqFeature::Gene::Transcript - A feature representing a transcript
17
18							=head1 SYNOPSIS
19
20							# See documentation of methods.
21
22							=head1 DESCRIPTION
23
24							A feature representing a transcript.
25
26							=head1 FEEDBACK
27
28							=head2 Mailing Lists
29
30							User feedback is an integral part of the evolution of this and other
31							Bioperl modules. Send your comments and suggestions preferably to one
32							of the Bioperl mailing lists. Your participation is much appreciated.
33
34							bioperl-l@bioperl.org - General discussion
35							http://bioperl.org/wiki/Mailing_lists - About the mailing lists
36
37							=head2 Support
38
39							Please direct usage questions or support issues to the mailing list:
40
41							I
42
43							rather than to the module maintainer directly. Many experienced and
44							reponsive experts will be able look at the problem and quickly
45							address it. Please include a thorough description of the problem
46							with code and data examples if at all possible.
47
48							=head2 Reporting Bugs
49
50							Report bugs to the Bioperl bug tracking system to help us keep track
51							the bugs and their resolution. Bug reports can be submitted via the
52							web:
53
54							https://github.com/bioperl/bioperl-live/issues
55
56							=head1 AUTHOR - Hilmar Lapp
57
58							Email hlapp@gmx.net
59
60							=head1 APPENDIX
61
62							The rest of the documentation details each of the object methods. Internal methods are usually preceded with a _
63
64							=cut
65
66
67							# Let the code begin...
68
69							package Bio::SeqFeature::Gene::Transcript;
70	9			9		878	use strict;
	9					11
	9					242
71
72
73	9			9		589	use Bio::PrimarySeq;
	9					19
	9					187
74
75	9			9		39	use base qw(Bio::SeqFeature::Generic Bio::SeqFeature::Gene::TranscriptI);
	9					12
	9					2502
76
77							sub new {
78	96			96	1	214	my ($caller, @args) = @_;
79	96					269	my $self = $caller->SUPER::new(@args);
80	96					261	$self->_register_for_cleanup(\&transcript_destroy);
81	96					232	my ($primary) = $self->_rearrange([qw(PRIMARY)],@args);
82
83	96	100				222	$primary = 'transcript' unless $primary;
84	96					266	$self->primary_tag($primary);
85	96	50				191	$self->strand(0) if(! defined($self->strand()));
86	96					232	return $self;
87							}
88
89
90							=head2 promoters
91
92							Title : promoters()
93							Usage : @proms = $transcript->promoters();
94							Function: Get the promoter features/sites of this transcript.
95
96							Note that OO-modeling of regulatory elements is not stable yet.
97							This means that this method might change or even disappear in a
98							future release. Be aware of this if you use it.
99
100							Returns : An array of Bio::SeqFeatureI implementing objects representing the
101							promoter regions or sites.
102							Args :
103
104
105							=cut
106
107							sub promoters {
108	9			9	1	14	my ($self) = @_;
109	9					19	return $self->get_feature_type('Bio::SeqFeature::Gene::Promoter');
110							}
111
112							=head2 add_promoter
113
114							Title : add_promoter()
115							Usage : $transcript->add_promoter($feature);
116							Function: Add a promoter feature/site to this transcript.
117
118
119							Note that OO-modeling of regulatory elements is not stable yet.
120							This means that this method might change or even disappear in a
121							future release. Be aware of this if you use it.
122
123							Returns :
124							Args : A Bio::SeqFeatureI implementing object.
125
126
127							=cut
128
129							sub add_promoter {
130	9			9	1	19	my ($self, $fea) = @_;
131	9					20	$self->_add($fea,'Bio::SeqFeature::Gene::Promoter');
132							}
133
134							=head2 flush_promoters
135
136							Title : flush_promoters()
137							Usage : $transcript->flush_promoters();
138							Function: Remove all promoter features/sites from this transcript.
139
140							Note that OO-modeling of regulatory elements is not stable yet.
141							This means that this method might change or even disappear in a
142							future release. Be aware of this if you use it.
143
144							Returns : the removed features as a list
145							Args : none
146
147
148							=cut
149
150							sub flush_promoters {
151	0			0	1	0	my ($self) = @_;
152	0					0	return $self->_flush('Bio::SeqFeature::Gene::Promoter');
153							}
154
155							=head2 exons
156
157							Title : exons()
158							Usage : @exons = $gene->exons();
159							($inital_exon) = $gene->exons('Initial');
160							Function: Get all exon features or all exons of specified type of this
161							transcript.
162
163							Exon type is treated as a case-insensitive regular expression and
164							is optional. For consistency, use only the following types:
165							initial, internal, terminal.
166
167							Returns : An array of Bio::SeqFeature::Gene::ExonI implementing objects.
168							Args : An optional string specifying the primary_tag of the feature.
169
170
171							=cut
172
173							sub exons {
174	111			111	1	837	my ($self, $type) = @_;
175	111					197	return $self->get_unordered_feature_type('Bio::SeqFeature::Gene::ExonI',
176							$type);
177							}
178
179							=head2 exons_ordered
180
181							Title : exons_ordered
182							Usage : @exons = $gene->exons_ordered();
183							@exons = $gene->exons_ordered("Internal");
184							Function: Get an ordered list of all exon features or all exons of specified
185							type of this transcript.
186
187							Exon type is treated as a case-insensitive regular expression and
188							is optional. For consistency, use only the following types:
189
190							Returns : An array of Bio::SeqFeature::Gene::ExonI implementing objects.
191							Args : An optional string specifying the primary_tag of the feature.
192
193							=cut
194
195							sub exons_ordered {
196	4			4	1	29	my ($self,$type) = @_;
197	4					9	return $self->get_feature_type('Bio::SeqFeature::Gene::ExonI', $type);
198							}
199
200							=head2 add_exon
201
202							Title : add_exon()
203							Usage : $transcript->add_exon($exon,'initial');
204							Function: Add a exon feature to this transcript.
205
206							The second argument denotes the type of exon. Mixing exons with and
207							without a type is likely to cause trouble in exons(). Either
208							leave out the type for all exons or for none.
209
210							Presently, the following types are known: initial, internal,
211							terminal, utr, utr5prime, and utr3prime (all case-insensitive).
212							UTR should better be added through utrs()/add_utr().
213
214							If you wish to use other or additional types, you will almost
215							certainly have to call exon_type_sortorder() in order to replace
216							the default sort order, or mrna(), cds(), protein(), and exons()
217							may yield unexpected results.
218
219							Returns :
220							Args : A Bio::SeqFeature::Gene::ExonI implementing object.
221							A string indicating the type of the exon (optional).
222
223
224							=cut
225
226							sub add_exon {
227	509			509	1	835	my ($self, $fea, $type) = @_;
228	509	50				1315	if(! $fea->isa('Bio::SeqFeature::Gene::ExonI') ) {
229	0					0	$self->throw("$fea does not implement Bio::SeqFeature::Gene::ExonI");
230							}
231	509					976	$self->_add($fea,'Bio::SeqFeature::Gene::Exon', $type);
232							}
233
234							=head2 flush_exons
235
236							Title : flush_exons()
237							Usage : $transcript->flush_exons();
238							$transcript->flush_exons('terminal');
239							Function: Remove all or a certain type of exon features from this transcript.
240
241							See add_exon() for documentation about types.
242
243							Calling without a type will not flush UTRs. Call flush_utrs() for
244							this purpose.
245							Returns : the deleted features as a list
246							Args : A string indicating the type of the exon (optional).
247
248
249							=cut
250
251							sub flush_exons {
252	0			0	1	0	my ($self, $type) = @_;
253	0					0	return $self->_flush('Bio::SeqFeature::Gene::Exon',$type);
254							}
255
256							=head2 introns
257
258							Title : introns()
259							Usage : @introns = $gene->introns();
260							Function: Get all intron features this gene structure.
261
262							Note that this implementation generates these features
263							on-the-fly, that is, it simply treats all regions between
264							exons as introns, assuming that exons do not overlap. A
265							consequence is that a consistent correspondence between the
266							elements in the returned array and the array that exons()
267							returns will exist only if the exons are properly sorted
268							within their types (forward for plus- strand and reverse
269							for minus-strand transcripts). To ensure correctness the
270							elements in the array returned will always be sorted.
271
272							Returns : An array of Bio::SeqFeature::Gene::Intron objects representing
273							the intron regions.
274							Args :
275
276
277							=cut
278
279							sub introns {
280	1			1	1	506	my ($self) = @_;
281	1					2	my @introns = ();
282	1					3	my @exons = $self->exons();
283	1					2	my ($strand, $rev_order);
284
285							# if there's 1 or less exons we're done
286	1	50				3	return () unless($#exons > 0);
287							# record strand and order (a minus-strand transcript is likely to have
288							# the exons stacked in reverse order)
289	1					2	foreach my $exon (@exons) {
290	1					3	$strand = $exon->strand();
291	1	50				4	last if $strand; # we're done if we've got 1 or -1
292							}
293	1	50				3	$rev_order = ($exons[0]->end() < $exons[1]->start() ? 0 : 1);
294
295							# Make sure exons are sorted. Because we assume they don't overlap, we
296							# simply sort by start position.
297	1	50	33			7	if((! defined($strand)) \|\| ($strand != -1) \|\| (! $rev_order)) {
			33
298							# always sort forward for plus-strand transcripts, and for negative-
299							# strand transcripts that appear to be unsorted or forward sorted
300	4					6	@exons = map { $_->[0] } sort { $a->[1] <=> $b->[1] }
	4					6
301	1		50			3	map { [ $_, $_->start * ($_->strand \|\| 1)] } @exons;
	4					6
302							} else {
303							# sort in reverse order for transcripts on the negative strand and
304							# found to be in reverse order
305	0					0	@exons = map { $_->[0] } sort { $b->[1] <=> $a->[1] } map { [ $_, $_->start()] } @exons;
	0					0
	0					0
	0					0
306							}
307							# loop over all intervening gaps
308	1		66			7	while ((my $exonA = shift (@exons)) &&(my $exonB = shift(@exons))){
309	3					12	my $intron = Bio::SeqFeature::Gene::Intron->new(-primary=>'intron');
310	3					7	$intron->upstream_Exon($exonA);
311	3					7	$intron->downstream_Exon($exonB);
312	3	50				7	$intron->attach_seq($self->entire_seq) if $self->entire_seq;
313	3					5	unshift(@exons,$exonB);
314	3					11	push @introns,$intron;
315							}
316	1					3	return @introns;
317							}
318
319							=head2 poly_A_site
320
321							Title : poly_A_site()
322							Usage : $polyAsite = $transcript->poly_A_site();
323							Function: Get/set the poly-adenylation feature/site of this transcript.
324							Returns : A Bio::SeqFeatureI implementing object representing the
325							poly-adenylation region.
326							Args : A Bio::SeqFeatureI implementing object on set, or FALSE to flush
327							a previously set object.
328
329
330							=cut
331
332							sub poly_A_site {
333	31			31	1	56	my ($self, $fea) = @_;
334	31	100				53	if ($fea) {
335	11					28	$self->_add($fea,'Bio::SeqFeature::Gene::Poly_A_site');
336							}
337	31					58	return ($self->get_feature_type('Bio::SeqFeature::Gene::Poly_A_site'))[0];
338							}
339
340							=head2 utrs
341
342							Title : utrs()
343							Usage : @utr_sites = $transcript->utrs('utr3prime');
344							@utr_sites = $transcript->utrs('utr5prime');
345							@utr_sites = $transcript->utrs();
346							Function: Get the features representing untranslated regions (UTR) of this
347							transcript.
348
349							You may provide an argument specifying the type of UTR. Currently
350							the following types are recognized: utr5prime utr3prime for UTR on the
351							5' and 3' end of the CDS, respectively.
352
353							Returns : An array of Bio::SeqFeature::Gene::UTR objects
354							representing the UTR regions or sites.
355							Args : Optionally, either utr3prime, or utr5prime for the the type of UTR
356							feature.
357
358
359							=cut
360
361							sub utrs {
362	3			3	1	5	my ($self, $type) = @_;
363	3					7	return $self->get_feature_type('Bio::SeqFeature::Gene::UTR',$type);
364
365							}
366
367							=head2 add_utr
368
369							Title : add_utr()
370							Usage : $transcript->add_utr($utrobj, 'utr3prime');
371							$transcript->add_utr($utrobj);
372							Function: Add a UTR feature/site to this transcript.
373
374							The second parameter is optional and denotes the type of the UTR
375							feature. Presently recognized types include 'utr5prime' and 'utr3prime'
376							for UTR on the 5' and 3' end of a gene, respectively.
377
378							Calling this method is the same as calling
379							add_exon($utrobj, 'utr'.$type). In this sense a UTR object is a
380							special exon object, which is transcribed, not spliced out, but
381							not translated.
382
383							Note that the object supplied should return FALSE for is_coding().
384							Otherwise cds() and friends will become confused.
385
386							Returns :
387							Args : A Bio::SeqFeature::Gene::UTR implementing object.
388
389
390							=cut
391
392							sub add_utr {
393	2			2	1	4	my ($self, $fea, $type) = @_;
394	2					7	$self->_add($fea,'Bio::SeqFeature::Gene::UTR',$type);
395							}
396
397							=head2 flush_utrs
398
399							Title : flush_utrs()
400							Usage : $transcript->flush_utrs();
401							$transcript->flush_utrs('utr3prime');
402							Function: Remove all or a specific type of UTR features/sites from this
403							transcript.
404
405							Cf. add_utr() for documentation about recognized types.
406							Returns : a list of the removed features
407							Args : Optionally a string denoting the type of UTR feature.
408
409
410							=cut
411
412							sub flush_utrs {
413	0			0	1	0	my ($self, $type) = @_;
414	0					0	return $self->_flush('Bio::SeqFeature::Gene::UTR',$type);
415							}
416
417							=head2 sub_SeqFeature
418
419							Title : sub_SeqFeature
420							Usage : @feats = $transcript->sub_SeqFeature();
421							Function: Returns an array of all subfeatures.
422
423							This method is defined in Bio::SeqFeatureI. We override this here
424							to include the exon etc features.
425
426							Returns : An array Bio::SeqFeatureI implementing objects.
427							Args : none
428
429
430							=cut
431
432							sub sub_SeqFeature {
433	9			9	1	18	my ($self) = @_;
434	9					11	my @feas;
435
436							# get what the parent already has
437	9					36	@feas = $self->SUPER::sub_SeqFeature();
438							# add the features we have in addition
439	9					30	push(@feas, $self->exons()); # this includes UTR features
440	9					28	push(@feas, $self->promoters());
441	9	100				20	push(@feas, $self->poly_A_site()) if($self->poly_A_site());
442	9					28	return @feas;
443							}
444
445							=head2 flush_sub_SeqFeature
446
447							Title : flush_sub_SeqFeature
448							Usage : $transcript->flush_sub_SeqFeature();
449							$transcript->flush_sub_SeqFeature(1);
450							Function: Removes all subfeatures.
451
452							This method is overridden from Bio::SeqFeature::Generic to flush
453							all additional subfeatures like exons, promoters, etc., which is
454							almost certainly not what you want. To remove only features added
455							through $transcript->add_sub_SeqFeature($feature) pass any
456							argument evaluating to TRUE.
457
458							Example :
459							Returns : none
460							Args : Optionally, an argument evaluating to TRUE will suppress flushing
461							of all transcript-specific subfeatures (exons etc.).
462
463
464							=cut
465
466							sub flush_sub_SeqFeature {
467	0			0	1	0	my ($self,$fea_only) = @_;
468
469	0					0	$self->SUPER::flush_sub_SeqFeature();
470	0	0				0	if(! $fea_only) {
471	0					0	$self->flush_promoters();
472	0					0	$self->flush_exons();
473	0					0	$self->flush_utrs();
474	0					0	$self->poly_A_site(0);
475							}
476							}
477
478
479							=head2 cds
480
481							Title : cds
482							Usage : $seq = $transcript->cds();
483							Function: Returns the CDS (coding sequence) as defined by the exons
484							of this transcript and the attached sequence.
485
486							If no sequence is attached this method will return false.
487
488							Note that the implementation provided here returns a
489							concatenation of all coding exons, thereby assuming that
490							exons do not overlap.
491
492							Note also that you cannot set the CDS via this method. Set
493							a single CDS feature as a single exon, or derive your own
494							class if you want to store a predicted CDS.
495
496							Example :
497							Returns : A Bio::PrimarySeqI implementing object.
498							Args :
499
500							=cut
501
502							sub cds {
503	4			4	1	23	my ($self) = @_;
504	4					42	my @exons = $self->exons_ordered(); #this is always sorted properly according to strand
505	4					5	my $strand;
506
507	4	50				11	return unless(@exons);
508							# record strand (a minus-strand transcript must have the exons sorted in
509							# reverse order)
510	4					8	foreach my $exon (@exons) {
511	40	100	100			63	if(defined($exon->strand()) && (! $strand)) {
512	5					9	$strand = $exon->strand();
513							}
514	40	50	66			63	if($exon->strand() && (($exon->strand() * $strand) < 0)) {
515	0					0	$self->throw("Transcript mixes coding exons on plus and minus ".
516							"strand. This makes no sense.");
517							}
518							}
519	4					30	my $cds = $self->_make_cds(@exons);
520	4	50				10	return unless $cds;
521	4					16	return Bio::PrimarySeq->new('-id' => $self->seq_id(),
522							'-seq' => $cds,
523							'-alphabet' => "dna");
524							}
525
526							=head2 protein
527
528							Title : protein()
529							Usage : $protein = $transcript->protein();
530							Function: Get the protein encoded by the transcript as a sequence object.
531
532							The implementation provided here simply calls translate() on the
533							object returned by cds().
534
535							Returns : A Bio::PrimarySeqI implementing object.
536							Args :
537
538
539							=cut
540
541							sub protein {
542	0			0	1	0	my ($self) = @_;
543	0					0	my $seq;
544
545	0					0	$seq = $self->cds();
546	0	0				0	return $seq->translate() if $seq;
547	0					0	return;
548							}
549
550							=head2 mrna
551
552							Title : mrna()
553							Usage : $mrna = $transcript->mrna();
554							Function: Get the mRNA of the transcript as a sequence object.
555
556							The difference to cds() is that the sequence object returned by
557							this methods will also include UTR and the poly-adenylation site,
558							but not promoter sequence (TBD).
559
560							HL: do we really need this method?
561
562							Returns : A Bio::PrimarySeqI implementing object.
563							Args :
564
565
566							=cut
567
568							sub mrna {
569	1			1	1	321	my ($self) = @_;
570	1					2	my ($seq, $mrna, $elem);
571
572							# get the coding part
573	1					4	$seq = $self->cds();
574	1	50				4	if(! $seq) {
575	0					0	$seq = Bio::PrimarySeq->new('-id' => $self->seq_id(),
576							'-alphabet' => "rna",
577							'-seq' => "");
578							}
579							# get and add UTR sequences
580	1					3	$mrna = "";
581	1					3	foreach $elem ($self->utrs('utr5prime')) {
582	1					4	$mrna .= $elem->seq()->seq();
583							}
584	1					4	$seq->seq($mrna . $seq->seq());
585	1					2	$mrna = "";
586	1					3	foreach $elem ($self->utrs('utr3prime')) {
587	1					3	$mrna .= $elem->seq()->seq();
588							}
589	1					4	$seq->seq($seq->seq() . $mrna);
590	1	50				3	if($self->poly_A_site()) {
591	1					3	$seq->seq($seq->seq() . $self->poly_A_site()->seq()->seq());
592							}
593	1	50				3	return if($seq->length() == 0);
594	1					2	return $seq;
595							}
596
597							sub _get_typed_keys {
598	0			0		0	my ($self, $keyprefix, $type) = @_;
599	0					0	my @keys = ();
600	0					0	my @feas = ();
601
602							# make case-insensitive
603	0	0				0	$type = ($type ? lc($type) : "");
604							# pull out all feature types that exist and match
605	0					0	@keys = grep { /^_$keyprefix$type/i; } (keys(%{$self}));
	0					0
	0					0
606	0					0	return @keys;
607							}
608
609							sub _make_cds {
610	4			4		12	my ($self,@exons) = @_;
611	4					8	my $cds = "";
612
613	4					10	foreach my $exon (@exons) {
614	40	100	66			91	next if((! defined($exon->seq())) \|\| (! $exon->is_coding()));
615	38					84	my $phase = length($cds) % 3;
616							# let's check the simple case
617	38	100	100			89	if((! defined($exon->frame())) \|\| ($phase == $exon->frame())) {
618							# this one fits exactly, or frame of the exon is undefined (should
619							# we warn about that?); we bypass the $exon->cds() here (hmm,
620							# not very clean style, but I don't see where this screws up)
621	37					71	$cds .= $exon->seq()->seq();
622							} else {
623							# this one is probably from exon shuffling and needs some work
624	1					3	my $seq = $exon->cds(); # now $seq is guaranteed to be in frame 0
625	1	50				4	next if(! $seq);
626	1					2	$seq = $seq->seq();
627							# adjustment needed?
628	1	50				3	if($phase > 0) {
629							# how many Ns can we chop off the piece to be added?
630	0					0	my $n_crop = 0;
631	0	0				0	if($seq =~ /^(n+)/i) {
632	0					0	$n_crop = length($1);
633							}
634	0	0				0	if($n_crop >= $phase) {
635							# chop off to match the phase
636	0					0	$seq = substr($seq, $phase);
637							} else {
638							# fill in Ns
639	0					0	$seq = ("n" x (3-$phase)) . $seq;
640							}
641							}
642	1					3	$cds .= $seq;
643							}
644							}
645	4					16	return $cds;
646							}
647
648							=head2 features
649
650							Title : features
651							Usage : my @features=$transcript->features;
652							Function: returns all the features associated with this transcript
653							Returns : a list of SeqFeatureI implementing objects
654							Args : none
655
656
657							=cut
658
659
660							sub features {
661	254			254	1	265	my $self = shift;
662	254	50				238	return grep { defined } @{$self->{'_features'} \|\| []};
	1674					2274
	254					555
663							}
664
665							=head2 features_ordered
666
667							Title : features_ordered
668							Usage : my @features=$transcript->features_ordered;
669							Function: returns all the features associated with this transcript,
670							in order by feature start, according to strand
671							Returns : a list of SeqFeatureI implementing objects
672							Args : none
673
674
675							=cut
676
677							sub features_ordered{
678	0			0	1	0	my ($self) = @_;
679	0	0				0	return $self->_stranded_sort(@{$self->{'_features'} \|\| []});
	0					0
680							}
681
682
683							sub get_unordered_feature_type{
684	158			158	0	240	my ($self, $type, $pri)=@_;
685	158					168	my @list;
686	158					269	foreach ( $self->features) {
687	1143	100				2030	if ($_->isa($type)) {
688	773	100	100			1046	if ($pri && $_->primary_tag !~ /$pri/i) {
689	35					42	next;
690							}
691	738					833	push @list,$_;
692							}
693							}
694	158					424	return @list;
695
696							}
697
698							sub get_feature_type {
699	47			47	0	56	my ($self)=shift;
700	47					77	return $self->_stranded_sort($self->get_unordered_feature_type(@_));
701							}
702
703							#This was fixed by Gene Cutler - the indexing on the list being reversed
704							#fixed a bad bug. Thanks Gene!
705							sub _flush {
706	0			0		0	my ($self, $type, $pri)=@_;
707	0					0	my @list=$self->features;
708	0					0	my @cut;
709	0					0	for (reverse (0..$#list)) {
710	0	0	0			0	if (defined $list[$_] &&
711							$list[$_]->isa($type)) {
712	0	0	0			0	if ($pri && $list[$_]->primary_tag !~ /$pri/i) {
713	0					0	next;
714							}
715	0					0	push @cut, splice @list, $_, 1; #remove the element of $type from @list
716							#and return each of them in @cut
717							}
718							}
719	0					0	$self->{'_features'}=\@list;
720	0					0	return reverse @cut;
721							}
722
723							sub _add {
724	531			531		785	my ($self, $fea, $type, $pri)=@_;
725	531					4927	require Bio::SeqFeature::Gene::Promoter;
726	531					2983	require Bio::SeqFeature::Gene::UTR;
727	531					1210	require Bio::SeqFeature::Gene::Exon;
728	531					3005	require Bio::SeqFeature::Gene::Intron;
729	531					3025	require Bio::SeqFeature::Gene::Poly_A_site;
730
731	531	50				1209	if(! $fea->isa('Bio::SeqFeatureI') ) {
732	0					0	$self->throw("$fea does not implement Bio::SeqFeatureI");
733							}
734	531	100	100			1756	if(! $fea->isa($type) \|\| $pri) {
735	382					680	$fea=$self->_new_of_type($fea,$type,$pri);
736							}
737	531	100				934	if (! $self->strand) {
738	87					148	$self->strand($fea->strand);
739							} else {
740	444	50				639	if ($self->strand * $fea->strand == -1) {
741	0					0	$self->throw("$fea is on opposite strand from $self");
742							}
743							}
744
745	531					1457	$self->_expand_region($fea);
746	531	0	33			1022	if(defined($self->entire_seq()) && (! defined($fea->entire_seq())) &&
			33
747							$fea->can('attach_seq')) {
748	0					0	$fea->attach_seq($self->entire_seq());
749							}
750	531	50				1096	if (defined $self->parent) {
751	0					0	$self->parent->_expand_region($fea);
752							}
753	531					575	push(@{$self->{'_features'}}, $fea);
	531					1013
754	531					1150	1;
755							}
756
757							sub _stranded_sort {
758	47			47		71	my ($self,@list)=@_;
759	47					55	my $strand;
760	47					61	foreach my $fea (@list) {
761	78	100				128	if($fea->strand()) {
762							# defined and != 0
763	64	100				99	$strand = $fea->strand() if(! $strand);
764	64	50				89	if(($fea->strand() * $strand) < 0) {
765	0					0	$strand = undef;
766	0					0	last;
767							}
768							}
769							}
770	47	100	100			118	if (defined $strand && $strand == - 1) { #reverse strand
771	20					33	return map { $_->[0] } sort {$b->[1] <=> $a->[1]} map { [$_, $_->start] } @list;
	52					110
	32					37
	52					80
772							} else { #undef or forward strand
773	27					51	return map { $_->[0] } sort {$a->[1] <=> $b->[1]} map { [$_, $_->start] } @list;
	26					87
	7					16
	26					56
774							}
775							}
776
777							sub _new_of_type {
778	382			382		535	my ($self, $fea, $type, $pri)= @_;
779	382					346	my $primary;
780	382	100				534	if ($pri) {
781	363					381	$primary = $pri; #can set new primary tag if desired
782							} else {
783	19					99	($primary) = $type =~ /.*::(.+)/; #or else primary is just end of type string
784							}
785	382					499	bless $fea,$type;
786	382					786	$fea->primary_tag($primary);
787	382					539	return $fea;
788							}
789
790							sub transcript_destroy {
791	96			96	0	117	my $self = shift;
792							# We're going to be really explicit to insure memory leaks
793							# don't occur
794	96					173	foreach my $f ( $self->features ) {
795	531					526	$f = undef;
796							}
797	96					220	$self->parent(undef);
798							}
799
800							1;