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1 tDNA (771 bp), nuclear DNA (3100 bp), and 51 microsatellite loci.
2 ticulitermes grassei using eight polymorphic microsatellite loci.
3 analyzing the large-scale genomic data from microsatellite loci.
4 reen sea turtles, Chelonia mydas, using four microsatellite loci.
5 ll parishes except one were genotyped for 12 microsatellite loci.
6 l lines, were assayed for polymorphism at 94 microsatellite loci.
7 ence data and variation at seven chloroplast microsatellite loci.
8 vening domain II and compared to 11 unlinked microsatellite loci.
9 ariation at five closely linked dinucleotide microsatellite loci.
10 d to mtDNA cytochrome b, intron AM2B1 and 15 microsatellite loci.
11 630 subjects, at 362 autosomal dinucleotide microsatellite loci.
12 terozygosity (LOH) analysis for specific DNA microsatellite loci.
13 cross the Mediterranean were genotyped at 14 microsatellite loci.
14 y "discontinuous LOH" for one or more of the microsatellite loci.
15 ifferent allelic profiles and frequencies at microsatellite loci.
16 pulations using both chloroplast and nuclear microsatellite loci.
17 poral changes in allele frequencies at seven microsatellite loci.
18 linkage disequilibrium between CCR5 and two microsatellite loci.
19 ed by tracking length variability in several microsatellite loci.
20 eny from these trees were genotyped at eight microsatellite loci.
21 ssful for rapid, semiautomated genotyping of microsatellite loci.
22 ise mutation model, which is appropriate for microsatellite loci.
23 ounced signature on rapidly evolving nuclear microsatellite loci.
24 nelumbiifolia, by genotyping populations at microsatellite loci.
25 data from mitochondrial sequences and eight microsatellite loci.
26 e design of PCR primers flanking polymorphic microsatellite loci.
27 nt structuring of populations based on eight microsatellite loci.
28 The new germplasm also was genotyped for 12 microsatellite loci.
29 ns (Procyon lotor; n=91) and genotyped at 11 microsatellite loci.
30 t, we identified 119 potentially informative microsatellite loci.
31 control group of primers from ten anonymous microsatellite loci.
32 eds and a closely related wild species at 23 microsatellite loci.
33 cent migration across volcanoes using eleven microsatellite loci.
34 clones containing simple sequence repeat, or microsatellite, loci.
36 half of all loci genotyped (i.e., all eight microsatellite loci, 12 of 16 allozyme loci and 44% of t
38 aches, GenoTan was able to genotype 94.9% of microsatellite loci accurately from simulated data with
39 trosideros polymorpha, for variation at nine microsatellite loci across 23 populations on young Hawai
41 by the biallelic marker M173 and by the four microsatellite loci alleles into two major subdivisions:
42 rees (n=185) were mapped and genotyped at 12 microsatellite loci, allowing us to positively identify
43 ed mutation rates in selectable genes and at microsatellite loci, although mutations in these genes c
44 have examined differences in diversity at 60 microsatellite loci among human population samples from
45 terns of genomic diversity for ninety feline microsatellite loci among previously characterized popul
46 boon linkage map consists primarily of human microsatellite loci amplified using published human PCR
47 ted in testcrosses, genetic distances at 108 microsatellite loci and 14 sequenced genes are highly va
48 dividuals using alleles at eight loci (seven microsatellite loci and a nucleotide substitution in the
50 cells partially corrects instability at the microsatellite loci and also the substitution and frames
51 es from 18 cancer types at more than 200,000 microsatellite loci and constructed a genomic classifier
52 ularity, the characterisation of polymorphic microsatellite loci and development of suitable markers
53 evolution will require the use of additional microsatellite loci and diallelic genetic markers with l
56 notyped adult and seedling Spartina using 17 microsatellite loci and mapped their locations in three
60 ata consisted of allele frequencies of eight microsatellite loci and of the Rb(4.12) and Rb(5.10) chr
61 or cross-species amplification of homologous microsatellite loci and studied some of the characterist
63 We used species-diagnostic mitochondrial and microsatellite loci and the Y chromosome Sry gene to det
65 Genetic differentiation was measured over 10 microsatellite loci and, to determine any effects of sel
67 also scored at 57 RAPD-SSCP loci, 5 (TAG)(n) microsatellite loci, and 6 sequence-tagged RAPD loci.
68 istant basins in Chile were genotyped for 13 microsatellite loci, and allocated, through probabilisti
69 distinct chicken breeds was genotyped for 27 microsatellite loci, and individual multilocus genotypes
70 ht rare-event biallelic polymorphisms, seven microsatellite loci, and internal structural analysis of
71 pattern of genetic isolation by distance at microsatellite loci, and it implies that in addition to
72 he O. nubilalis TE has inserted at (GAAA)(n) microsatellite loci, and was named the microsatellite-as
73 of 16 Type I (coding gene) loci, 14 Type II (microsatellite) loci, and 1 endogenous retroviral elemen
75 a situation becoming increasingly common as microsatellite loci are developed in increasing numbers
76 ur data indicate that mutational dynamics at microsatellite loci are more complicated than the genera
78 ectable alterations at two or more different microsatellite loci) are significantly more likely to co
80 d for caution in the use of repeat counts at microsatellite loci as secure indicators of allelic rela
83 in color mutants, were genotyped with twelve microsatellite loci, being eleven of them identified as
84 e comparison of the repeat sizes at multiple microsatellite loci between tumor and matched normal tis
85 e methods rely on the detection of amplified microsatellite loci by fluorescence-based DNA sequencing
86 g role for repeat disruptions in stabilizing microsatellite loci by reducing the substrate for polyme
87 detailed investigation was performed on five microsatellite loci by sequencing each microsatellite, t
88 hat the pattern of variation across unlinked microsatellite loci can be used to test whether populati
89 pair and further support the hypothesis that microsatellite loci can function as molecular tumor cloc
90 s exhibit marked instability at 12 different microsatellite loci composed of repeat units of 1 to 4 b
93 es from pathotype 3 of P. sorghi, 36 flanked microsatellite loci containing simple repeats, including
95 that spans this locus and is flanked by the microsatellite loci D13S153 and D13S163 was lost in 85%
96 udes the D18S858 locus and is flanked by the microsatellite loci D18S41 and D18S381, was lost in eigh
98 ormal and tumor tissue was analyzed at eight microsatellite loci (D2S119, D2S123, D2S147, D10S197, D1
99 tional 50 esophageal tumors, the polymorphic microsatellite loci D3S1300 and D3S1313 were used to eva
100 potential for using genetic methods based on microsatellite loci data to compare historical trends in
101 ome-wide scan was performed using a panel of microsatellite loci determined to be informative for thi
104 zone, we analyzed chromosomal inversions, 16 microsatellite loci distributed genomewide, and 834 bp o
107 epeats of simple sequences indicate that the microsatellite loci evolve via some of forward-backward
109 n of neutral genetic differentiation at nine microsatellite loci (F(ST)) as an indicator of expected
112 of genetic diversity and differentiation at microsatellite loci flanking all 4 genes indicated that
113 utionary history of dhfr alleles, we assayed microsatellite loci flanking dhfr along chromosome 4.
114 associated with sulfadoxine resistance and 5 microsatellite loci flanking dhps in order to investigat
115 doxine-pyrimethamine (SP) resistance and the microsatellite loci flanking these genes were genotyped
116 c variation at the mitochondrial and nuclear microsatellite loci for 148 individuals, we identified t
117 The analyses were based on genotypes at 11 microsatellite loci for 318 individuals, spanning three
119 so presented, demonstrating the potential of microsatellite loci for resolving relationships among ac
120 roe deer, we investigated variability at 12 microsatellite loci for Siberian roe deer from ten local
121 re, we used newly-developed and existing DNA microsatellite loci for the brooding coral Porites astre
122 ollected and analyzed at cytochrome b and 11 microsatellites loci for investigating genetic variation
123 30 bp of mitochondrial control region and 12 microsatellite loci from 94 individuals stranded around
124 to the distributions of the allele sizes at microsatellite loci from a set of populations, grouped b
125 l to a dataset of genotypes at 377 autosomal microsatellite loci from human populations indicate high
126 approach to identify inherited variation of microsatellite loci from short sequence reads without pa
131 of population samples from minisatellite and microsatellite loci has resurrected the interest of the
132 has resulted in the disruption of (GAAA)(n) microsatellite loci, has impacted the application of mic
133 ons and frequencies of five Candida albicans microsatellite loci have been determined for strains iso
134 al that, on average, the non-disease-causing microsatellite loci have mutation rates inversely relate
135 n structure using genotypes at 377 autosomal microsatellite loci in 1056 individuals from 52 populati
136 rformed an independent genome scan using 751 microsatellite loci in 127 CD-affected relative pairs fr
137 five major histocompatibility loci and three microsatellite loci in 14 populations; the performance o
138 s of heterozygosity (LOH) was analysed in 19 microsatellite loci in 20 grade III invasive transitiona
139 ion of the repeat regions of three noncoding microsatellite loci in 58 species of the Polistinae, a s
140 The method is applied to a data set of 32 microsatellite loci in a Finnish population and the resu
141 typed with more than 350 highly polymorphic microsatellite loci in a genome-wide linkage screen.
142 We examined patterns of variation at 20 microsatellite loci in a sample of 23 natural isolates o
143 ts using modest numbers of loci-e.g. , seven microsatellite loci in an example using genotype data fr
146 Analysis of three data sets from surveys of microsatellite loci in ethnographically defined populati
147 ed fox population expansion, we genotyped 21 microsatellite loci in modern and historical (1835-1941)
150 from three nuclear introns, and genotyped 18 microsatellite loci in order to examine the patterns of
151 high frequency of heterozygote deficiency at microsatellite loci in resistant populations, and a nega
152 or helping to interpret genetic variation at microsatellite loci in species with a very recent histor
153 extend this model, a genetic linkage map of microsatellite loci in the feline genome has been constr
154 Application of this measure to data on 18 microsatellite loci in the nine human populations leads
155 d rates of sequence variation at a number of microsatellite loci in the parasite genome, and led to i
158 exchanges, by haplotype analysis of flanking microsatellite loci in tk(-/-) LOH mutants collected fro
159 lteration in the size of at least two of the microsatellite loci in tumor DNA when compared with norm
160 nd class IIalpha MH-linked markers and eight microsatellite loci in two Atlantic salmon populations i
162 s were detectable by analysis of polymorphic microsatellite loci, including a novel (CA)n locus 7.9 k
163 c analyses of genetic distances based on the microsatellite loci indicate a close genetic relationshi
166 lotypes based on six diallelic loci and five microsatellite loci indicates that some Icelandic haplog
167 efined by grouping alleles at closely spaced microsatellite loci into haplotypes, or generated by rep
168 t statistic, ln RV, proposed for identifying microsatellite loci involved in recent selective sweeps.
171 e at 54 perfect (uninterrupted) dinucleotide microsatellite loci is estimated by direct genotyping of
173 m that generates high levels of variation at microsatellite loci lags far behind the application of t
174 r sites, strongly influenced by five outlier microsatellite loci located in conserved intergenic regi
175 PCR with primers for 75 highly polymorphic microsatellite loci located on the major autosome arms w
176 rgence, we compared differentiation at eight microsatellite loci (measured as F(ST)) to differentiati
177 mposition of African tea based on 23 nuclear microsatellites loci (nSSRs) and three cpDNA intergenic
178 ies were analyzed along with genotypes at 12 microsatellite loci of 40 individuals coexisting in 3 Me
180 satellite loci (D1S80, D17S30, ApoB), and 27 microsatellite loci of di-, tri-, or tetranucleotide rep
183 ty is that there is little or no mutation at microsatellite loci on a non-recombining chromosome such
184 32 contiguous units and assayed at multiple microsatellite loci on chromosome 11q, a region frequent
187 informative biallelic markers as well as 10 microsatellite loci on the nonrecombining region of the
188 astic lesions, for genetic alterations at 15 microsatellite loci on the short arm of chromosome 8.
189 th America were surveyed for variation at 16 microsatellite loci on the X, second, and third chromoso
192 stimates depend on the mutation rates at the microsatellite loci, our results support the hypothesis
193 Combining the multi-allelic variation at the microsatellite loci (poly(A) tail and DYS19) with the YA
195 locations of QTL with the locations of five microsatellite loci previously shown to vary clinally in
196 f normal and tumor genotypes using PCR-based microsatellite loci provides considerable advantages ove
198 of 300 individuals were genotyped using five microsatellite loci, representing 100 individuals with a
199 ons of approximately 6000 human dinucleotide microsatellite loci, representing chromosomes 1-22, from
204 notyping of 95% of the trees at nine nuclear microsatellite loci revealed that levels of genetic dive
206 This was compared to variation at other microsatellite loci scattered throughout the sheep genom
207 ions that a certain fraction of mutations at microsatellite loci should produce alleles that are iden
210 on/deletion mutation at six repeat-sequence (microsatellite) loci showed each Atmsh2-1 line to have e
212 kage disequilibrium and sequence analyses on microsatellite loci spanning a region of approximately 3
214 ture of selection, we survey variation in 26 microsatellite loci spanning an approximately 32-cM regi
216 herefore be used to determine copy number of microsatellite loci spread throughout the human genome.
221 the ABI 7700 and based on amplifications of microsatellite loci that contain (CA)n repeats where the
222 and 130 pairs, we found variation at 7 of 21 microsatellite loci that successfully amplified, the rem
223 We analyze variation at 10 Y chromosome microsatellite loci that were typed in 506 males represe
225 imens for mutations in K-RAS and analyzed 10 microsatellite loci tightly linked to the tumor suppress
229 tigate this question, we used a series of 15 microsatellite loci to analyze 15 separate AH lesions mi
230 ong sparrows from 23 populations using seven microsatellite loci to assess genetic differentiation am
233 viduals from 20 populations at four variable microsatellite loci to contrast genetic diversity and st
234 e putative suppressor in 8p23 by using eight microsatellite loci to create a high resolution deletion
236 minutus) were genotyped at two hypervariable microsatellite loci to document conclusively the number
238 yped 233 American badgers in Wisconsin at 12 microsatellite loci to identify alternative statistical
239 f these BACs and used them, along with seven microsatellite loci, to detect and map homozygous deleti
240 f heterozygosity (LOH) at multiple PCR-based microsatellite loci using semiautomated fluorescent DNA
241 r the entire African elephants' range for 16 microsatellite loci, using 315 tissue and 84 scat sample
243 measured by allele length variation at five microsatellite loci was compared with estimates calculat
244 We show here that diversity across eight microsatellite loci was consistently and substantially l
245 ergence in the size of different alleles) at microsatellite loci was examined by sequencing multiple
247 ll strains, and overall genetic variation at microsatellite loci was low, relative to most other spec
250 retic separation of PCR amplified oligo A or microsatellite loci was used to identify candidate sampl
252 pulation expansion on genetic variability at microsatellite loci, we consider a population that evolv
254 l approaches and genotyping a large panel of microsatellite loci, we show that colony membership, mot
256 In the case of genealogical inference using microsatellite loci, we use coalescent simulations to sh
257 hree and six tri- and tetranucleotide repeat microsatellite loci were analyzed in 3720 samples collec
258 In a search for parental relationships, microsatellite loci were analyzed in more than 300 grape
261 on could be generalized, an additional eight microsatellite loci were characterized and sequenced fro
264 nt knowledge of microsatellite evolution, 20 microsatellite loci were examined for 126 accessions of
265 derived from the donor or recipient, unique microsatellite loci were examined to establish chimeric
270 smission of alleles at FRAXA, FRAXE and four microsatellite loci were recorded for all individuals.
272 The patterns of mutation and evolution at 13 microsatellite loci were studied in the filamentous fung
273 some sections of the genus, yet chloroplast microsatellite loci were too variable to provide any use
278 or counteracting the continuous expansion of microsatellite loci, which is the logical consequence of
279 ation to 8 positionally mapped gene-anchored microsatellite loci whose positions were known in the ge
281 estigated among British Restharrows using 10 microsatellite loci with 21 Restharrow populations analy
282 Fifty-five primers designed from conserved microsatellite loci with an E-value of E-10 or lower amp
283 al and nuclear nucleotide differences and 20 microsatellite loci with nonoverlapping allele-size rang
287 somal loci (17 introns and 3 exon segments), microsatellite loci, X- and Y-linked zinc-finger protein
288 ding abundant di-, tri-, and tetranucleotide microsatellite loci yielded access to precisely localize
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