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Table view (28 sequence regions)

Original order	Download FASTA	Accession	Bit score	Type	Start	End	Description	Species	View context
0		X07673.1	N/A	seed	425	1,032	Yeast SNR30 gene	Saccharomyces cerevisiae (baker's yeast)
1		AABY01000047.1	N/A	seed	17,961	17,352	Saccharomyces paradoxus NRRL Y-17217 contig_50, whole genome shotgun sequence.	Saccharomyces paradoxus NRRL Y-17217
2		AACH01000215.1	N/A	seed	7,327	6,713	Saccharomyces mikatae IFO 1815 YM4906-Contig2705, whole genome shotgun sequence.	Saccharomyces mikatae IFO 1815
3		AACI02000330.1	N/A	seed	3,807	4,421	Saccharomyces kudriavzevii IFO 1802 YM6553-Contig02.1708, whole genome shotgun sequence.	Saccharomyces kudriavzevii IFO 1802
4		AACA01000009.1	N/A	seed	17,253	17,860	Saccharomyces bayanus MCYC 623 contig_123, whole genome shotgun sequence.	Saccharomyces bayanus MCYC 623
0		BK006945.2	739.70	full	198,784	199,392	TPA: Saccharomyces cerevisiae S288C chromosome XII, complete sequence.	Saccharomyces cerevisiae S288c
1		JH796792.1	733.80	full	3,840	4,454	Saccharomyces kudriavzevii IFO 1802 unplaced genomic scaffold c1684, whole genome shotgun sequence.	Saccharomyces kudriavzevii IFO 1802
2		CM001574.1	676.60	full	188,336	188,945	Saccharomyces arboricola H-6 chromosome XII, whole genome shotgun sequence.	Saccharomyces arboricola H-6
3		HE650824.1	193.50	full	566,110	565,624	Kazachstania africana CBS 2517 chromosome 4, complete genome	Kazachstania africana CBS 2517
4		HE580271.1	180.90	full	380,465	380,960	Naumovozyma dairenensis CBS 421 chromosome 5, complete genome	Naumovozyma dairenensis CBS 421
5		HE612862.1	178.40	full	590,969	590,526	Tetrapisispora phaffii CBS 4417 chromosome 7, complete genome	Tetrapisispora phaffii CBS 4417
6		CP059267.1	176.40	full	633,138	632,717	CP059267.1 Torulaspora sp. CBS 2947 strain CBS2947 chromosome 1	Torulaspora sp. CBS 2947
7		HE978314.1	171.40	full	921,916	921,328	Kazachstania naganishii CBS 8797 chromosome 1, complete genome	Kazachstania naganishii CBS 8797
8		FXLY01000002.1	163.40	full	2,826,254	2,825,726	Kazachstania saulgeensis genome assembly, contig: scaffold_01	Kazachstania saulgeensis
9		CR380947.2	159.30	full	342,845	343,420	Candida glabrata strain CBS138 chromosome A complete sequence.	Candida glabrata
10		CR382126.1	158.80	full	1,622,323	1,621,813	Kluyveromyces lactis strain NRRL Y-1140 chromosome F complete sequence.	Kluyveromyces lactis
11		HE616742.1	156.80	full	352,735	352,287	Torulaspora delbrueckii CBS 1146 chromosome 1, complete genome	Torulaspora delbrueckii CBS 1146
12		HE576752.1	156.60	full	844,090	843,615	Naumovozyma castellii CBS 4309 chromosome 1, complete genome	Naumovozyma castellii CBS 4309
13		LT598485.1	144.70	full	854,932	855,362	Lachancea fermentati genome assembly, chromosome: C	Lachancea fermentati
14		CP058607.1	132.10	full	559,480	559,054	CP058607.1 Zygotorulaspora mrakii strain NRRL Y-6702 chromosome 4	Zygosaccharomyces mrakii
15		LT598469.1	129.20	full	32,167	31,754	Lachancea mirantina genome assembly, chromosome: G	Lachancea mirantina
16		CP002502.1	126.30	full	169,600	169,157	Eremothecium cymbalariae DBVPG#7215 chromosome 6, complete sequence.	Eremothecium cymbalariae DBVPG#7215
17		CU928173.1	124.30	full	734,574	734,126	Zygosaccharomyces rouxii strain CBS732 chromosome A complete sequence.	Zygosaccharomyces rouxii CBS 732
18		CU928169.1	123.50	full	814,543	814,995	Lachancea thermotolerans CBS 6340 chromosome E complete sequence.	Lachancea thermotolerans CBS 6340
19		AE016819.5	118.10	full	817,931	818,373	Ashbya gossypii ATCC 10895 chromosome VI, complete sequence.	Ashbya gossypii ATCC 10895
20		LT598455.1	115.30	full	159,161	159,643	Lachancea dasiensis CBS 10888 genome assembly, chromosome: E	Lachancea dasiensis CBS 10888
21		DS480410.1	101.50	full	40,438	40,891	Vanderwaltozyma polyspora DSM 70294 KpolScaffold1025 genomic scaffold, whole genome shotgun sequence.	Vanderwaltozyma polyspora DSM 70294
22		LN736361.1	96.60	full	445,994	445,545	Lachancea lanzarotensis strain CBS 12615 genome assembly, scaffold: LALA0S02	Lachancea lanzarotensis

There are various ways to view or download the seed alignments that we store. You can use a sequence viewer to look at them, or you can look at a plain text version of the sequence in a variety of different formats. More...

View options

You can view Rfam seed alignments in your browser in various ways. Choose the viewer that you want to use and click the "View" button to show the alignment in a pop-up window.

Formatting options

You can view or download Rfam seed alignments in several formats. Check either the "download" button, to save the formatted alignment, or "view", to see it in your browser window, and click "Generate".

Download

Download a gzip-compressed, Stockholm-format file containing the seed alignment for this family. You may find RALEE useful when viewing sequence alignments.

Submit a new alignment

We're happy receive updated seed alignments for new or existing families. Submit your new alignment and we'll take a look.

In this page you can view static images showing the secondary structure of this family using a variety of colouring schemes:

Conservation (cons): this plot colours each character by how well conserved it is. A site with 100% sequence conservation is coloured red, 0% is violet.

Covariation (cov): this plot colours each base-pair according to how much the corresponding nucleotides are co-varying. A base-pair position at which every pair of nucleotides is co-variant with respect to every other pair in the alignment gets a score of 2 and is coloured red. Conversely, a base-pair position at every pair is anti-co-variant with respect to every other pair (e.g. lots of mutations to non-canonical pairs) gets a score of -2 and is coloured violet. Further information on this metric can be found in this document.

Sequence entropy (ent): this plot colours each character by how under- or over-represented the residues at the site are. Sites where one or more nucleotides are over-represented while the other nucleotides are either non-existent or near the background frequencies, receive positive scores; sites where all the nucleotides are under-represented receive negative scores. Further information on this metric can be found in this document.

Fraction of canonical basepairs (fcbp): this plot colours each base-pair by the percentage of canonical basepairs (A:U, C:G, G:U) which are found in the corresponding position in the alignment. A pair of sites with 100% canonical pairs is coloured red, a site with 0% is violet.

Maximum parse of the covariance model (maxcm): this plot takes the covariance model for the family and generates the sequence with the maximum possible score for that model. Each character is coloured by how many bits it contributes to the total score.

Sequence: for most of the above cases, the representative sequence used for the backbone is the most informative sequence (MIS). Any residue that has a higher frequency than than the background frequency is projected into the IUPAC redundancy codes.

Normal: this plot simply colours each stem loop

R-chie (rchie): arc diagrams showing secondary structure, calculated using the R-chie package. The consensus secondary structure is visualized as arc diagrams on top of each diagram, where a basepair in an arc, connect two columns of the block of sequences below. The block of sequences below represent the multiple sequence alignment of the Rfam seed, where each sequence is a horizontal strip. Sequences in the alignments are ordered so sequences that best fit the structure are on top, and those that do not fit as well are towards the bottom. For seed alignments for over 500 sequences, 500 random sequences were chosen. Rfam entries without sturcture have a blank plot. Colour information can be found on the R-chie FAQ.

You can also view the secondary structure in the VARNA applet. The applet is shown in a separate pop-up window.

Acknowledgements

The bulk of the code for generating these graphics was kindly supplied by Andreas Gruber and Ivo Hofacker. The statistics were implemented by Rfam.

The VARNA applet is developed by Yann Ponty et al:

The R-chie arc diagrams were calculated using R-chie:

These trees were generated using either a maximum likelihood approach or neighbour-joining. If the number of sequences in the alignment was less than or equal to 64 then the maximum likelihood approach of Rivas and Eddy was used [1]. For families with more than 64 sequences in the alignment the neighbour-joining approach with F84 distances as implemented in phylip was used [2].

Note: You can also download the data file for the seed tree.

We do not have tree information for this family. This is most likely due to the size of the family and the number of species covered. For very large families it is too computationally expensive to calculate trees and the resulting tree images would be too large to display in a browser.

Loading structure mapping...

There are 1 motifs which match this family.

This section shows the Rfam motifs that match sequences within the seed alignment of this family. Users should be aware that the motifs are structural constructs and do not necessarily conform to taxonomic boundaries in the way that Rfam families do. More...

Original order	Motif Accession	Motif Description	Number of Hits	Fraction of Hits	Sum of Bits	Image
7	RM00029	UNCG tetraloop	3	0.600	39.4