The document summarizes a study examining the effects of vaginal septa on reproductive performance in BALB/cByJNarl mice. Some key points:
- 14.2% of female mice in the colony had vaginal septa, which obstructed about half of the vaginal opening on average.
- Mice with septa had lower rates of copulatory plugs (51% vs 72%) and pregnancy (27% vs 54%) than mice without septa. They also had fewer uterine sperm and higher rates of dystocia.
- Septa sometimes ruptured during breeding or birth, allowing fertility, but rates remained lower than in non-septate mice. Pups of septate
Understanding of Models use for biomedical research who have similar physiological function like humans ,and the how to generate and which models are useful
Austin Andrology is an open access, peer reviewed, scholarly journal dedicated to publish articles covering all areas of Andrology.
The journal aims to promote research communications and provide a forum for doctors, researchers, physicians and healthcare professionals to find most recent advances in all the areas of Andrology. Austin Andrology accepts original research articles, reviews, mini reviews, case reports and rapid communication covering all aspects of andrology.
Austin Andrology strongly supports the scientific up gradation and fortification in related scientific research community by enhancing access to peer reviewed scientific literary works. Austin Publishing Group also brings universally peer reviewed journals under one roof thereby promoting knowledge sharing, mutual promotion of multidisciplinary science.
Understanding of Models use for biomedical research who have similar physiological function like humans ,and the how to generate and which models are useful
Austin Andrology is an open access, peer reviewed, scholarly journal dedicated to publish articles covering all areas of Andrology.
The journal aims to promote research communications and provide a forum for doctors, researchers, physicians and healthcare professionals to find most recent advances in all the areas of Andrology. Austin Andrology accepts original research articles, reviews, mini reviews, case reports and rapid communication covering all aspects of andrology.
Austin Andrology strongly supports the scientific up gradation and fortification in related scientific research community by enhancing access to peer reviewed scientific literary works. Austin Publishing Group also brings universally peer reviewed journals under one roof thereby promoting knowledge sharing, mutual promotion of multidisciplinary science.
CONCEPT
HISTORY OF XENOTRANSPLANTATION
IMPORTANCE OF XENOTRANSPLANTATION
CHOOSING OF DONOR SPECIES
XENOTRANSPLANTATION REJECTION
GUIDELINES ON XENO-TRANSPLANTATION BY ICMR
RECENT RESEARCH ON XENOTRANSPLANTATION
Artificial Insemination and its Importance in Marine Crustaceans: A Review by Chandan Haldar*, Shyam Kumar and Raju Ram in crimson publishers: Journal of Marine Biology
Artificial Insemination (AI) is a tool for genetic manipulation in the crustacean stock including shrimp and crabs. It is seen as one of the means for propagating shrimp culture to new areas by controlled reproduction. But there are few studies on the reproduction and embryology of marine crustaceans whereas other groups of freshwater crustaceans have received much attention, and their embryology is better documented. So for the proper development of the marine production it is now necessary to focus on the artificial insemination technique in marine species also. In the current review we have discussed on the different tool and techniques used in artificial insemination of marine crustaceans In future, more number of research and development works must be conducted to increase the production of marine crustaceans by controlled reproduction through artificial insemination.
https://crimsonpublishers.com/eimbo/fulltext/EIMBO.000524.php
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Ovarian development in Cosmopolites sordidus Germar (Coleoptera: Curculionidae)IOSRJAVS
This study was undertaken to determine the ovarian development of banana weevils. Results indicated that female banana weevils have a meroistic and telotrophic ovariole. Four (4) stages of ovarian development were observed. Newly emerged females belonged to stage I, characterized by virtual absence of oocytes in female germarium; while fully mature adult females belonged to stage IV, characterized by the presence of mature, chorionated eggs in female calyces. The intermediate stages II and III were characterized by presence of small, undeveloped oocytes, and presence of developed but non-chorionated oocytes in the vitellarium of female ovarioles, respectively. The preoviposition period in this insect was found to range between 27 and 41 DAE and egg-loads in calyces ranged from 2 to 11. All females at ovarian stage IV (i.e. ages 25 DAE and above) were found to have mated, and were ready for ovulation and oviposition. Monitoring the reproductive phenology of crop pests may be helpful for predicting (forecasting) potential outbreaks. it could also aptly guide the timing of control options, and also aid varietal screening works. Field samplings that result in heavy female populations and with predominant numbers at final stages of ovarian development, may be a danger signal that should trigger instant interventions
It was observed that swim rate of sperm changes in microgravity. Sperm swim with higher velocity in microgravity. The fertilization might be affected by this mobility changes in sperm and this led to reduction in sperm motility under microgravity. Follicle Stimulating Hormone FSH that is responsible for ovulation in women by triggering egg maturity and stimulating sperm production in men can be damaged by microgravity. Therefore, ovulations and triggering of egg maturity and production of sperm may not take place. Higher acidity of outer vagina due to fluid distribution at the upper part of the body might kill the sperm or reduce sperm counts. Microgravity environment reduced the thickening of the endometrium to the extent that eggs cannot be planted cause non implantations . Jaiyeola O. Paul | Oluwafemi A. Funmilola | Abdullahi S. Ayegba "Microgravity and Infertility" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-6 , October 2019, URL: https://www.ijtsrd.com/papers/ijtsrd29408.pdf Paper URL: https://www.ijtsrd.com/other-scientific-research-area/other/29408/microgravity-and-infertility/jaiyeola-o-paul
description of transgenic animals and production with desired traits using different methods and their applications and their advantages and disadvantages
Livestock sector is an important sector in indian economy. To boost the productive performance of existing livestock population in india, biotechnolgy plays a key role to fullfill this.
Differences in the endometrial transcript profile during the receptive period between women who were refractory to implantation and those who achieved pregnancy.
By Luis Alberto Velásquez Cumplido
CONCEPT
HISTORY OF XENOTRANSPLANTATION
IMPORTANCE OF XENOTRANSPLANTATION
CHOOSING OF DONOR SPECIES
XENOTRANSPLANTATION REJECTION
GUIDELINES ON XENO-TRANSPLANTATION BY ICMR
RECENT RESEARCH ON XENOTRANSPLANTATION
Artificial Insemination and its Importance in Marine Crustaceans: A Review by Chandan Haldar*, Shyam Kumar and Raju Ram in crimson publishers: Journal of Marine Biology
Artificial Insemination (AI) is a tool for genetic manipulation in the crustacean stock including shrimp and crabs. It is seen as one of the means for propagating shrimp culture to new areas by controlled reproduction. But there are few studies on the reproduction and embryology of marine crustaceans whereas other groups of freshwater crustaceans have received much attention, and their embryology is better documented. So for the proper development of the marine production it is now necessary to focus on the artificial insemination technique in marine species also. In the current review we have discussed on the different tool and techniques used in artificial insemination of marine crustaceans In future, more number of research and development works must be conducted to increase the production of marine crustaceans by controlled reproduction through artificial insemination.
https://crimsonpublishers.com/eimbo/fulltext/EIMBO.000524.php
For more Open access journals in Crimson Publishers
Please click on: https://crimsonpublishers.com/
For more articles in Examines in Marine Biology & Oceanography
Please click on: https://crimsonpublishers.com/eimbo/index.php
For more details track the below URL
https://www.linkedin.com/in/chyler-henley-crimson-publishers/
Follow on Publons: https://publons.com/publisher/6342/crimson-publishers
Follow on Linkedin : https://www.linkedin.com/company/crimsonpublishers
Ovarian development in Cosmopolites sordidus Germar (Coleoptera: Curculionidae)IOSRJAVS
This study was undertaken to determine the ovarian development of banana weevils. Results indicated that female banana weevils have a meroistic and telotrophic ovariole. Four (4) stages of ovarian development were observed. Newly emerged females belonged to stage I, characterized by virtual absence of oocytes in female germarium; while fully mature adult females belonged to stage IV, characterized by the presence of mature, chorionated eggs in female calyces. The intermediate stages II and III were characterized by presence of small, undeveloped oocytes, and presence of developed but non-chorionated oocytes in the vitellarium of female ovarioles, respectively. The preoviposition period in this insect was found to range between 27 and 41 DAE and egg-loads in calyces ranged from 2 to 11. All females at ovarian stage IV (i.e. ages 25 DAE and above) were found to have mated, and were ready for ovulation and oviposition. Monitoring the reproductive phenology of crop pests may be helpful for predicting (forecasting) potential outbreaks. it could also aptly guide the timing of control options, and also aid varietal screening works. Field samplings that result in heavy female populations and with predominant numbers at final stages of ovarian development, may be a danger signal that should trigger instant interventions
It was observed that swim rate of sperm changes in microgravity. Sperm swim with higher velocity in microgravity. The fertilization might be affected by this mobility changes in sperm and this led to reduction in sperm motility under microgravity. Follicle Stimulating Hormone FSH that is responsible for ovulation in women by triggering egg maturity and stimulating sperm production in men can be damaged by microgravity. Therefore, ovulations and triggering of egg maturity and production of sperm may not take place. Higher acidity of outer vagina due to fluid distribution at the upper part of the body might kill the sperm or reduce sperm counts. Microgravity environment reduced the thickening of the endometrium to the extent that eggs cannot be planted cause non implantations . Jaiyeola O. Paul | Oluwafemi A. Funmilola | Abdullahi S. Ayegba "Microgravity and Infertility" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-6 , October 2019, URL: https://www.ijtsrd.com/papers/ijtsrd29408.pdf Paper URL: https://www.ijtsrd.com/other-scientific-research-area/other/29408/microgravity-and-infertility/jaiyeola-o-paul
description of transgenic animals and production with desired traits using different methods and their applications and their advantages and disadvantages
Livestock sector is an important sector in indian economy. To boost the productive performance of existing livestock population in india, biotechnolgy plays a key role to fullfill this.
Differences in the endometrial transcript profile during the receptive period between women who were refractory to implantation and those who achieved pregnancy.
By Luis Alberto Velásquez Cumplido
An Experimental Study of Natural Selection and Relative Fitness .docxamrit47
An Experimental Study of Natural Selection and Relative Fitness
Introduction (2/3 or 2/4)
Biological evolution is a fundamental concept in biology that helps us understand the natural world i.e., the history and diversity of life on Earth. At the most basic definition, biological evolution is descent with modification. That is, subsequent generations change over time. Biological evolution can be subdivided into microevolution and macroevolution. Microevolution involves small-scale changes in allele frequencies in a population from one generation to the next. Macroevolution encompasses large-scale changes that produces different species from common ancestors over many generations. Since macroevolution requires an extensive period of time (most are beyond human lifetimes), macroevolutionary studies are largely observational. In other words, we cannot create experiments to test macroevolutionary hypotheses. Instead, we observe patterns and infer the processes from those patterns. Alternatively, microevolution studies require a relatively short period of time such that hypotheses testing can be observational or experimentational (we can create experiments).
Performing microevolution experiments requires an understanding of the Hardy-
Weinberg equilibrium principle. Hardy-Weinberg equilibrium is a simple mathematical model
that assumes a single population’s gene pool does not change in frequency from one generation
to the next. The model is represented by two algebraic equations: the allele frequency equation (p
+ q = 1) and the genotype frequency equation (p2 + 2pq + q2 = 1). To illustrate these equations,
let’s consider a simple dominant/recessive relationship of a character (mouse fur color,
represented by the letter “b”) with two traits (brown and white). This means we will have two
alleles and three genotypes. The lower-case b allele represents the white fur trait and the upper-
case B allele represents the brown fur trait, while the white fur phenotype is represented by the
ww genotype and the brown fur phenotype is represented by the WW and Ww genotypes. With
respect to the frequencies, f(w) is represented by q and f(W) is represented by p, while ww is 22
represented by q , Ww is represented by pq and WW is represented by p . This lab consists of using these equations to determine whether microevolution has occurred, so make sure you understand them.
In simpler terms, this means that if 60% of a population of mice have the white fur trait and 40% have the brown fur trait, this proportion will be the same in the next generation regardless of population size. There may be more individuals in the next generation, but the ratio remains the same (three white fur traits to two brown fur traits). As a principle, this expectation makes sense. However, there are mechanisms of evolutionary change that violate this Hardy- Weinberg equilibrium principle that need to be understood.
There are five recognized mechanisms that disrupt the Ha.
Clinical Manifestations of Plasmodium bergheiANKA Infection in Juvenile Mice:...AI Publications
Malaria is an important health and development challenge in Africa, Animalmodels most particularly mice, have long been employedto study malaria pathogenesis. Clinical manifestations due to Plasmodium bergheiANKA infection in juvenile mice as a model for understanding the complications ofcongenital malaria in neonates.Forty-five juvenile mice (5-7 days old) were acquired from University College Hospital, Ibadan and injected with 2 x 107 (0.2ml) Plasmodium berghei ANKA parasitized red blood cells (PRBCs). Mice were transported to the study site, kept in well ventilated cages and fed daily with a balanced ration. Every day after post-P. berghei infection, mice were monitored for mortality. Clinical manifestations ofexperimental cerebral malaria (ECM) was assessed and confirmed if at leastruffled fur, hunching, wobbly gait, limb paralysis, convulsions, or coma was observed. Each sign was given a score of 1. Animals with scores ≥4 were considered to have severe ECM.20 (44%) micewerelost due to natural cause (i.e. stress) at day 2 of the experiment. Between day 4 and 9, 25 (56%) of the studymice presented clinical signs of ECM which includes; ruffled fur 25(100%), hunching 21 (84%), wobbly gait 17 (68%), limb paralysis 20 (80%), convulsions 25 (100%) and subsequently died. Survival rate and severity of ECM in the mice differs, 22 (88.0%) had severe ECM and 3(12.0%) had mild ECM.This study has shown that parasite establishment and malaria complications can manifest as early as 4 days’postP. berghei infection in 5-7 days old mice.
Dynamic Aspects of Schistosoma Haematobium Infection as Experimental Model.pdfAlim A-H Yacoub Lovers
Abdul-Hussein H Awad, Alim A-H Yacoub, Sabeeh H Al-Mayah. Dynamic Aspects of Schistosoma Haematobium Infection as Experimental Model. Medical Journal of Basra University 1995;13(1&2):21-30
Detection of Plasmodium Species among Pregnant Women attending Antenatal Careiosrjce
IOSR Journal of Dental and Medical Sciences is one of the speciality Journal in Dental Science and Medical Science published by International Organization of Scientific Research (IOSR). The Journal publishes papers of the highest scientific merit and widest possible scope work in all areas related to medical and dental science. The Journal welcome review articles, leading medical and clinical research articles, technical notes, case reports and others.
1ScIeNtIFIc REPORTS | (2018) 8:1250 | DOI:10.1038/s41598-018-19638-x
www.nature.com/scientificreports
Histology, immunohistochemistry,
and in situ hybridization reveal
overlooked Ebola virus target
tissues in the Ebola virus disease
guinea pig model
Timothy K. Cooper1, Louis Huzella 1, Joshua C. Johnson 1, Oscar Rojas1, Sri Yellayi1,3,
Mei G. Sun2, Sina Bavari2, Amanda Bonilla1, Randy Hart1, Peter B. Jahrling 1, Jens H. Kuhn 1
& Xiankun Zeng 2
Survivors of Ebola virus infection may become subclinically infected, but whether animal models
recapitulate this complication is unclear. Using histology in combination with immunohistochemistry
and in situ hybridization in a retrospective review of a guinea pig confirmation-of-virulence study, we
demonstrate for the first time Ebola virus infection in hepatic oval cells, the endocardium and stroma of
the atrioventricular valves and chordae tendinae, satellite cells of peripheral ganglia, neurofibroblasts
and Schwann cells of peripheral nerves and ganglia, smooth muscle cells of the uterine myometrium
and vaginal wall, acini of the parotid salivary glands, thyroid follicular cells, adrenal medullary cells,
pancreatic islet cells, endometrial glandular and surface epithelium, and the epithelium of the vagina,
penis and, prepuce. These findings indicate that standard animal models for Ebola virus disease are not
as well-described as previously thought and may serve as a stepping stone for future identification of
potential sites of virus persistence.
Ebola virus disease (EVD) is a severe and frequently lethal affliction of humans caused by infection with any
of three members of the mononegavirus family Filoviridae: Bundibugyo virus (BDBV), Ebola virus (EBOV),
and Sudan virus (SUDV). A fourth virus, Taï Forest virus (TAFV), has thus far caused only a single reported
human infection, which was nonlethal1. EVD is an exotic disease with case numbers rarely surpassing the lower
hundreds1; however, from 2013–2016, EBOV caused an EVD outbreak in Western Africa encompassing 28,616
infections and 11,310 deaths in Guinea, Liberia, and Sierra Leone2. Long term sequelae in individual survivors of
acute EVD and the similar Marburg virus disease (MVD) and filovirus persistence followed by disease relapse or
sexual transmission had been reported before this outbreak3–8. However, observations during and following the
Western African EVD outbreak suggest that sequelae and filovirus persistence may be common events9. Reported
sequelae include arthralgia, cardiac valvulopathy, parotid gland inflammation, peripheral paresthesia or dyses-
thesia, and gastrointestinal motility disorders10–14. Semen may contain detectable EBOV RNA for more than 500
days following recovery, and EBOV RNA has been detected in breast milk of a subclinically infected mother15,16.
Replicating EBOV has been isolated from the cerebrospinal fluid of an EVD survivor suffering a disease relapse
and from the aqueous hu.
1. Vol 52, No 5
September 2013
Pages 520–523
Journal of the American Association for Laboratory Animal Science
Copyright 2013
by the American Association for Laboratory Animal Science
520
Vaginal septa in mice vary from a thin dorsoventral band of
tissue that bisects the vaginal orifice to a thick band that divides
the vaginal canal longitudinally (Figure 1). Microscopically,
the septum consists of fibrous connective tissue covered by
normal vaginal mucosa.1,3 Vaginal septa occur in many species,
including humans, multiple strains of laboratory mice, rats,
and dogs.1,2,6,9,10 Previous reports have indicated that genetic
background is important for the expression of this polygenic
anomaly in mice.1,11
While evaluating mice for copulatory plugs, animal care-
takers noticed a high incidence of vaginal septa in our SPF
BALB/cByJNarl colony. The BALB/cByJNarl subline was de-
rived from BALB/cByJ mice after more than 20 generations of
brother–sister mating in our facility. The C57BL/6J strain was
reported to have an increased incidence of vaginal septa after
several decades of inbreeding.3 The incidence in BALB/cJ mice
had been reported to be as high as 38%, but that in BALB/cBy
mice was only 1.3% to 3.2%.1,11 Here we sought to determine
the effects of vaginal septa on the reproduction performance
of BALB/cByJNarl mice. In this strain, the presence of vaginal
septa correlated with decreased intrauterine sperm count and
decreased reproductive performance.
Materials and Methods
Animals. This study was conducted in a BALB/cByJNarl
breeding colony in the animal facility of the National Labora-
tory Animal Center (Tainan, Taiwan), an AAALAC-accredited
program. The BALB/cByJNarl substrain was derived in 1995
from the BALB/cByJ founder line (The Jackson Laboratory,
Bar Harbor, ME). A total of 1480 virgin female mice were ex-
amined during the study period (March through December
2010). The mice were housed in open, wire-top cages in the
facility’s barrier production facility, which has a stringent
quality assurance program to ensure the health and genetic
integrity of the animals produced.7 Caging and bedding
(Aspen, Tapvei, Kortteinen, Finland) were autoclaved. Mice
received autoclaved rodent diet (diet 5010, PMI, St Louis,
MO) and autoclaved (121 °C, 20 min) reverse-osmosis water
ad libitum. Environmental temperature was maintained at 23
± 2 °C and humidity at 50% ± 10%, with a 12:12-h light:dark
cycle.5 All husbandry and sentinel surveillance practices strictly
followed the institutional guidelines to ensure that mice were
free of pneumonia virus of mice, Theiler encephalomyelitis
virus, minute virus of mice, mouse hepatitis virus, mouse
adenovirus, Sendai virus, lymphocytic choriomeningitis
virus, ectromelia (mousepox) virus, Hantaan virus, mouse
parvovirus, mouse norovirus, reovirus type 3, Mycoplasma
pulmonis, Bordetella bronchiseptica, Corynebacterium kutscheri,
Salmonella spp., Citrobacter rodentium, Pseudomonas aeruginosa,
Clostridium piliforme, Helicobacter spp., and endo- and ec-
toparasites.7 Quarterly genetic monitoring (11 microsatellite
markers: Mit446, Mit309, Mit5, Mit136, Mit78, Mit14, Mit226,
Mit184, Mit64, Mit19, and Mit210) confirmed a well-defined
genetic profile consistent with the BALB/cByJ strain. All
procedures were reviewed and approved by the facility’s
IACUC (approval number, NLAC[TN]-100-R-007).
Examination for vaginal septa. Female mice were examined
after weaning for the presence of a vaginal septum by using
a technique similar to that for checking for copulatory plugs.
Briefly, one set of forceps was used to lift mice by the tail,
while a second set of forceps was used to apply gentle exter-
nal pressure on the vagina to open the vaginal orifice. When
present, a vaginal septum was easily visualized as a longitu-
dinal, transverse, or oblique dorsal-to-ventral band of tissue
bisecting the vagina. To quantify obstruction of the vaginal
orifice by the vaginal septum, age- and weight-matched virgin
female mice (n = 16 septate, n = 16 nonseptate) were selected,
and photographs of their perineums were taken by using a
digital camera (Figure 1). The area (in mm2) of the vaginal
orifice was determined by using ImageJ software (National
Institutes of Health, Bethesda, MD). The percentage obstruc-
tion was calculated as:
Effects of Vaginal Septa on the Reproductive
Performance of BALB/cByJNarl Mice
Tsung-Keng Chang,1 Peiyin Ho,1 Chung-Tiang Liang,1 and Chun-Keung Yu1-3,*
From March through December 2010, the incidence of vaginal septa in our SPF breeding colony of BALB/cByJNarl mice
was 14.2%. In general, septa obstructed half of the vaginal orifice. Here we sought to determine the effect of this defect by
comparing the reproductive performance of affected (septate) mice with that of unaffected (nonseptate) mice. Our results
showed that the rates of both copulatory plugs and pregnancy were significantly lower in septate mice than in nonseptate
mice. Specifically, 23 of 45 bred septate female mice (51%) had vaginal plugs compared with 49 of 68 bred nonseptate females
(72%). Only 12 septate female mice (27%) had successful pregnancies, compared with 37 nonseptate females (54%). Septate mice
had a 1-logfold fewer intrauterine sperm after mating than did nonseptate mice. Three cases of dystocia were noted among
septate mice whereas none occurred in nonseptate mice. Septate dams had a higher percentage of septate pups (15.5%) than
did nonseptate dams (6.1%). Our findings indicate that vaginal septa affect the reproductive performance of laboratory mice
and that such a defect should be considered as an exclusion criterion for the selection of future breeders in a mouse colony.
Received: 05 Nov 2012. Revision requested: 04 Dec 2012. Accepted: 11 Mar 2013.
1National Laboratory Animal Center, National Applied Research Laboratories, Tainan,
Taiwan; 2Department of Microbiology and Immunology and 3Center of Infectious Dis-
ease and Signaling Research, College of Medicine, National Cheng Kung University,
Tainan, Taiwan.
*Corresponding author. Email: dckyu@nlac.narl.org.tw
2. 521
Reproductive performance in mice with vaginal septa
Breeding performance. To examine the effect of vaginal septa
on breeding performance, a total of 68 nonseptate and 45 septate
virgin female mice (age, 9 to 12 wk) each was mated with 1 of 20
(Average area of nonseptate vaginal orifice – Average area
of obstructed vaginal orifice) ÷ Average area of nonseptate
vaginal orifice × 100%.
Figure 1. The gross and histopathologic manifestations of vaginal septa. A primiparous female mouse has (A) a nonseptate vaginal orifice with
(B) a fully open vaginal space and (C) normal histologic appearance. A septate female mouse exhibits (D) a longitudinal vaginal septum with (E)
a smaller vaginal orifice. The septum is a dorsoventral band of connective tissue that extends longitudinally in the vagina canal. It is covered by
mucosa of stratified squamous keratinizing epithelium. Scale bar, 200 μm.
3. 522
Vol 52, No 5
Journal of the American Association for Laboratory Animal Science
September 2013
software (Systat Software, San Jose, CA). Results are expressed
as mean ± 1 SD. A P value of less than 0.05 was considered
statistically significant.
Results
Incidence of vaginal septum in BALB/cByJNarl mice. During
the 10-mo study period, 14.2% (210 of 1480) of BALB/cByJNarl
virgin female mice born in our facility were found to have a
vaginal septum. All but 2 of these septa were longitudinal in
orientation.
Obstruction of vaginal orifice by vaginal septum. The vaginal
orifice of septate female mice was obstructed on visual inspec-
tion (Figure 1). Measurement from digital images showed that
a vaginal septum approximately obstructed 49% of the vaginal
orifice of septate mice. Consequently, the vaginal orifice of
septate mice (n = 16; mean ± 1 SD, 1.36 ± 0.28 mm2) was sig-
nificantly (P < 0.0001) smaller than that of nonseptate mice
(n = 16; 2.67 ± 0.88 mm2).
Effect of vaginal septa on reproductive performance. In a
timed mating trail, in which female mice were mated at 1600
and checked for copulatory plugs at 0900 the next morning,
nonseptate mice had a significantly (χ2, P < 0.05) higher copula-
tory plug rate than did septate mice. Specifically, 49 of 68 (72%)
nonseptate mice had copulatory plugs, compared with 23 of
45 (51%) septate female mice. The female mice were further
monitored for successful pregnancy after mating. The preg-
nancy rate was significantly (χ2, P < 0.01) higher in nonseptate
mice than septate mice: 37 of 68 (54%) mice delivered litters
compared with 12 of 45 (27%) septate mice. In addition, no
dystocia occurred in the nonseptate group, whereas 3 cases were
confirmed in septate mice (Fisher exact test, P < 0.05). Among
mice with copulatory plugs, 37 of 49 (75.5%) nonseptate mice
had successful pregnancies, compared with 12 of 23 (52.2%)
septate mice (χ2, P < 0.05).
Rupture of vaginal septa during breeding or parturition.
Among the 23 septate mice with plugs after mating, 13 (56.5%)
experienced ruptured septa. These mice were fertile, and a
small-scale breeding study showed that they had a 50% copu-
latory rate (4 of 8 mice) and a 25% pregnancy rate (2 of 8 mice)
after mating.
Uterine sperm counts. To determine whether a vaginal sep-
tum interferes with the mating of septate mice, we counted the
number of sperm in the uteri shortly after mating. The aver-
age number of spermatozoa in the vagina of nonseptate mice
(1.2 ± 0.29 × 107/mL) was significantly (unpaired t test, P < 0.001)
higher than that of mice with vaginal septa (1.45 ± 1.17 × 106/mL).
Heritability of vaginal septa.Among the 131 female pups born
to 57 nonseptate dams, 8 (6.1%) had a vaginal septum, whereas
24 (15.5%) of the 155 female pups born to 64 septate dams car-
ried the defect (χ2, P < 0.05).
Histologic examination. Microscopic examination was consist-
ent with earlier findings.1 The vaginal septum of our mice was
a longitudinal band of tissue covered by a mucosa of stratified
squamous keratinizing epithelium (Figure 1 C and F), consistent
with normal vaginal mucosa.
Discussion
BALB/cByJ breeder mice were introduced to our facility in
1995 and maintained under SPF conditions. A new subline,
designated as BALB/cByJNarl, was established in 1998 after 10
generations of inbreeding, and there have been 32 additional
inbreeding generations since then. We demonstrated that
the incidence of vaginal septa in the BALB/cByJNarl subline
individually caged proven male breeder mice. The female mice
were introduced into the cage of the sire at 1600 and examined
for copulatory plugs at 0900 the following morning by using
the same technique as for vaginal septum. Mice with plugs then
were housed individually; those without plugs were group-
housed. All mated mice were examined by palpation at 14
d after mating to assess for pregnancy. Pregnant mice were
monitored for delivery or dystocia, which was defined as the
delivery of dead, full-term pups. When dystocia occurred, the
dam and surviving pups were euthanized to remove them
from the production colony. At the end of the study, nonsep-
tate successful dams remained in the breeding colony, and
septate dams were euthanized. The rate of copulatory plugs
was defined as:
No. of female mice with plugs ÷ the total no. of female
mice mated × 100%.
Pregnancy rate was defined as:
No. of female mice that delivered ÷ the total no. of female
mice mated × 100%.
The rate of dystocia rate was defined as:
No. of mice that experienced dystocia ÷ the total no. of
female mice mated × 100%.
The rate of plugged and pregnant mice was defined as:
No. of female mice with plugs that delivered ÷ the total no.
of female mice with plugs after mating × 100%.
Sperm count in the uterus. Six adult male mice that had at
least one successful mating record were housed individually.
Each male was pair-housed with a nonseptate female (n = 6)
and a female with a vaginal septum (n = 6) for periods of 1 wk
each; the order of mating with nonseptate or septate mice was
randomized for each male mouse. Female mice were examined
every 30 min after pairing for the presence of copulatory plugs;
those with plugs were euthanized immediately. The uterine
horns were removed by cutting at the cervical and ovarian ends.
Each uterine horn was flushed with 1 mL PBS.14 The number of
spermatozoa in 10 μL of the wash solution was counted imme-
diately on a Makler Counting Chamber (New York Microscope
Company, New York, NY).8
Heritability. Nonseptate (n = 57) and septate (n = 64) virgin
female mice at 9 wk of age were individually randomly mated
with 1 of 15 proven sires. Pregnant mice were housed individu-
ally in a cage with nesting materials. The female offspring of
these mice were examined for the presence of a vaginal septum
at 4 wk of age. At the end of the study, nonseptate dams and
pups remained in the breeding colony, whereas those with a
vaginal septum were euthanized.
Euthanasia method. Mice were euthanized by carbon dioxide
inhalation with or without cervical dislocation.
Histopathology. Two nonseptate and 6 septate female mice
were euthanized with carbon dioxide, and their vagina and
uteri were removed and fixed in 10% neutral buffered formalin.
Tissue samples were processed by routine methods and were
imbedded in paraffin wax. Sections (6 μm) were stained with
hematoxylin and eosin.
Statistical analyses. Frequency data were analyzed by using
the χ2 test (copulatory plug rate, pregnancy rate, and heredity)
or Fisher exact test (dystocia), and quantitative data (vaginal
orifice and sperm count) were analyzed by using an unpaired
Student t test. All statistics were analyzed by using SigmaPlot
4. 523
Reproductive performance in mice with vaginal septa
was much higher than that of the parental strain BALB/cBy
reported previously (14.2% versus1.3%),1 suggesting that the
trait became fixed during the establishment of the subline.
Breeding with nonseptate female mice reduced but did not
eliminate the trait in subsequent generations, consistent with
previous reports12 of the polygenic recessive nature of this
trait and the fact that male mice can carry relevant alleles also.
Our results show significant association between vaginal
septa and poor reproductive performance in mice. The effects of
vaginal septa on reproduction were clear. The 14.2% incidence
of vaginal septa reflects that 468 female mice with this defect
had been selected as breeders (among the total of 3300 female
breeders at our facility), corresponding to a considerable waste
of both time and money.
The presence of copulatory plugs in the vagina and sperm in
the uterus strongly indicated that septate mice could mate with
male mice. However, the decreases in plug rate, sperm count,
and pregnancy rate of septate mice imply decreased successful
intercourse. The 1.33-fold increase in time for a success mating
(data not shown) supported this assumption. In addition, 3
septate mice delivered dead pups (interpreted as dystocia),
compared with no dead pups delivered in the nonseptate group.
Therefore, although septate mice can successfully mate and
carry fetuses to full-term, they seem to be more susceptible to
dystocia than are nonseptate mice.
Grossly, more than 99% of the vaginal septa among our mice
were longitudinal. Imperforate vagina has not been seen in
BALB/cByJNarl mice, although a high incidence of this defect
has been noted in other strains of inbred mice.4,13 Importantly,
approximately half of the septa ruptured after the first mat-
ing, and the mice with ruptured septa were fertile but had
a poorer reproductive performance than that of nonseptate
female mice.
Collectively, our results indicate that genetic drift of sublines
can occur over time even with a strict brother–sister mat-
ing scheme12 and that vaginal septa affect the reproductive
performance of laboratory mice. Removing septate female
mice from a breeding colony may reduce the incidence of
vaginal septa in population, improve breeding performance,
and improve animal welfare by facilitating intercourse and
parturition.
Acknowledgment
We greatly appreciate the valuable technical support provided by
Misses Shiow-Ling Liao and Yi-Ying Chiu.
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