DiscovArray™ Probes / Content

The MOST CONTENT Available On Any Platform

The DiscovArray miRNA Expression Service, utilizing the Ambion miRChip V1, offers the most content available on any miRNA profiling platform, allowing you to interrogate a dramatically larger number of putative miRNAs.

Validated and exploratory content totaling > 13,000 candidate miRNAs from various sources.^†

In addition to Sanger content, other sources of candidate miRNAs have been included to discover novel expression patterns.

DiscovArray™ Ambion miRChip V1 content	Human	Rat	Mouse
Sanger miRBase 11.0	837 probes	350 probes	599 probes
DiscovArray™ content	623 probes	292 probes	361 probes
DiscovArray™ % of Sanger 11.0	74%	83%	60%
Exploratory content	>12,000 probes	Homology likely
Total probes	13,349 probes

Comparison to Sanger 11.0 Content

The following table offers both a conservative (left panels) and liberal (right panels) comparison of the Ambion miRChip V1 content to the Sanger 11.0 miRBase.

	DiscovArray™ Ambion miRChip V1 content
	Perfect match to unique Sanger microRNA sequences¹			Candidates likely to measure signal from a Sanger miRNA/precursors²
Species	DiscovArray™	Sanger 11.0	Coverage	DiscovArray™	Sanger 11.0	Coverage
Anopheles gambiae	37	44	84%	40	45	89%
Apis mellifera	37	51	73%	42	54	78%
Arabidopsis thaliana	71	154	46%	117	184	64%
Ateles geoffroyi	42	54	78%	45	60	75%
Bombyx mori	19	21	91%	19	21	91%
Bos taurus	115	125	92%	112	117	96%
Brassica napus	17	24	71%	41	46	89%
Brassica oleracea	0	1	0%	0	0	0%
Brassica rapa	0	1	0%	0	1	0%
Caenorhabditis briggsae	76	92	83%	79	95	83%
Caenorhabditis elegans	113	156	72%	113	154	73%
Canis familiaris	151	177	85%	179	203	88%
Carica papaya	1	1	100%	1	1	100%
Chlamydomonas reinhardtii	0	84	0%	0	49	0%
Ciona intestinalis	7	32	22%	10	34	29%
Ciona savignyi	7	25	28%	8	27	30%
Cricetulus griseus	1	1	100%	1	1	100%
Danio rerio	180	219	82%	315	337	94%
Dictyostelium discoideum	0	2	0%	0	2	0%
Drosophila melanogaster	72	152	47%	78	152	51%
Drosophila pseudoobscura	62	68	91%	73	73	100%
Epstein Barr virus	6	39	15%	5	23	22%
Fugu rubripes	108	109	99%	131	131	100%
Gallus gallus	126	131	96%	147	149	99%
Glycine max	15	15	100%	22	22	100%
Gorilla gorilla	81	81	100%	86	86	100%
Gossypium herbecium	1	1	100%	1	1	100%
Gossypium hirsutum	5	7	71%	10	13	77%
Gossypium rammindii	1	1	100%	2	2	100%
Herpes Simplex Virus 1	0	0	0%	0	1	0%
Homo sapiens	623	837	74%	502	678	74%
Human cytomegalovirus	14	17	82%	11	11	100%
Human immunodeficiency virus 1	0	4	0%	0	3	0%
Kaposi sarcoma-associated herpesvirus	16	17	94%	12	13	92%
Lagothrix lagotricha	45	45	100%	48	48	100%
Lemur catta	15	15	100%	16	16	100%
Macaca mulatta	337	480	70%	352	464	76%
Macaca nemestrina	71	71	100%	75	75	100%
Mareks disease virus	0	22	0%	0	13	0%
Mareks disease virus type 2	0	27	0%	0	17	0%
Medicago truncatula	14	17	82%	29	30	97%
Monodelphis domestica	91	110	83%	103	119	87%
Mouse cytomegalovirus	0	29	0%	0	18	0%
Mouse gammaherpesvirus 68	8	10	80%	9	9	100%
Mus musculus	361	599	60%	324	472	69%
Oikopleura dioica	1	63	2%	6	66	9%
Oryza sativa	92	142	65%	180	269	67%
Ovis aries	4	4	100%	4	4	100%
Pan paniscus	84	84	100%	89	89	100%
Pan troglodytes	81	92	88%	91	100	91%
Physcomitrella patens	14	187	8%	51	220	23%
Pinus taeda	5	25	20%	9	29	31%
Pongo pygmaeus	81	81	100%	84	84	100%
Populus trichocarpa	99	112	88%	215	234	92%
Pygathrix bieti	3	9	33%	7	11	64%
Rattus norvegicus	292	350	83%	258	287	90%
Rhesus lymphocryptovirus	0	22	0%	1	16	6%
Rhesus monkey rhadinovirus	0	11	0%	0	7	0%
Saccharum officinarum	10	10	100%	16	16	100%
Saguinus labiatus	40	40	100%	42	42	100%
Schmidtea mediterranea	1	73	1%	4	63	6%
Selaginella moellendorffii	5	60	8%	14	58	24%
Simian virus 40	2	2	100%	1	1	100%
Sorghum bicolor	39	39	100%	72	72	100%
Sus scrofa	53	53	100%	55	55	100%
Symphalangus syndactylus	4	10	40%	5	11	46%
Tetraodon nigroviridis	108	109	99%	132	132	100%
Triticum aestivum	8	31	26%	9	32	28%
Vitis vinifera	41	79	52%	116	140	83%
Xenopus laevis	7	7	100%	7	7	100%
Xenopus tropicalis	130	166	78%	160	184	87%
Zea mays	43	43	100%	96	96	100%
Total Coverage	4193	6073	69%	4882	6396	76%

1. Perfect match to unique Sanger microRNA sequences
The values reported as “Sanger 11.0” in this case are the number of unique mature miRNA sequences annotated in the Sanger miRBase for each organism. The values shown under "miRChip V1" are the number of these sequence-unique mature miRNAs that are probed by at least one miRChip V1 probe with a 100% perfect match. Therefore it reflects the most conservative number of Sanger mature miRNA, and the most conservative estimate of unique probes to these miRNA.

2. Candidates likely to measure signal from a Sanger miRNA/precursors
The values reported as "Sanger 11.0" in this case are the number of unique precursors annotated in the Sanger miRBase for each organism, regardless of whether a mature miRNA appears on multiple precursors. The values reported as "miRChip V1" are the number of these named unique precursors for which at least one probe on the miRChip V1 has at least 90% overlap with no internal mismatches. This table demonstrates what the miRChip is likely to detect based on the commonly referenced number of miRNAs in the Sanger miRBase.

Stay ahead of Sanger miRBase with a single chip

Profile your samples today using content which is likely to be in future releases of Sanger miRBase. Annotation files will be updated with each Sanger update to facilitate analysis of historical data sets relative to the latest Sanger annotations.

Open the window to exploratory content

The addition of exploratory content allows you to find novel miRNA expression patterns in specific tissues or disease states. An internal survey of ten normal human tissues compared the number of Sanger miRNAs detected to the number of exploratory miRNA seqences detected. A 28% detection rate for predicted human miRNAs was obtained using the DiscovArray Service.

Ambion miRChip V1 Oligo Probe Design

miRNAs are a highly evolutionarily conserved class of small non-coding RNAs that are recently found to be negative regulators of gene expression. The length of mature miRNAs range between 18 and 25 nucleotides (nt). The short minimal sequence available for hybridization and wide range of melting temperatures of miRNA sequences pose serious challenges for miRNA array design.

The design of the Ambion miRNA miRChip V1 was based on the Affymetrix GeneChip platform. The comprehensive content of 13,349 unique known and predicted miRNA mature sequences were selected from miRBase release 9.2 and other sources ^†. Unique mature miRNA sequences were defined as having at least one nucleotide base difference in pair wise comparison.

Two overlapping probes were designed for each mature miRNA candidate. The staggered probe design provides the flexibility required for probes to capture slight variations in the ends of the processed mature miRNA. For computationally predicted miRNA, this probe design strategy accounts for the uncertainty associated with predicting the precise cleavage site of the processed mature miRNA.

Interested in Asuragen's other miRNA services? [Click here]

†References:

1. Griffiths-Jones S, Grocock RJ, van Dongen S, Bateman A, Enright AJ. miRBase: miRNA sequences, targets and gene nomenclature. Nucleic Acids Res., 2006, 34, D140-D144.
2. Cummins, Proc Natl Acad Sci USA 103(10):3687-92, 2006);
3. Xie, Nature 434(7031):338-45, 2005);
4. Berezikov, Cell 120(1):21-4, 2005);
5. Bentwich, Nat Genet. 2005 Jul;37(7):766-70 (method for miRNA predictions).

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