Spatial Learning Is Impaired in Male Pubertal Rats Following Neonatal Daily but Not Randomly Spaced Maternal Deprivation.

Severe early life stress has long been associated with neuropsychological disorders in adulthood, including depression, schizophrenia, post-traumatic stress disorder, and memory dysfunction. To some extent, all of these conditions involve dysregulation of the hypothalamic-pituitary-adrenal (HPA) axis and reduced negative feedback inhibition of cortisol release in adulthood. However, the time course for mental health and hormonal outcomes across life stages and the attributes of early life stress that direct the behavioral and biological alterations is not fully understood. We designed our studies to compare outcomes of the two most common maternal deprivation schedules on cognitive ability prior to adulthood. We exposed rat pups to daily or randomly spaced maternal separation bouts within the first 3 weeks of life and examined cognitive performance, neurotrophic signaling, and stress and immune system markers during puberty. We found that the daily separation schedule impaired spatial learning while the randomly spaced schedule did not alter maze performance relative to normally reared control animals. Animals that underwent daily separation showed a tendency for reduced body weight compared to the randomly spaced condition, but there were no differences in adrenal weight. Thymus weight normalized by body weight was increased following daily separation compared to random separation and control conditions. Plasma corticosterone levels measured after behavior testing did not differ amongst experimental groups and there was no impact of TrKB receptor inhibition. Combined, the results show that different early life stress schedules produce different behavioral and biological outcomes when measured at puberty. Combined with prior findings from more mature animals, the results presented here suggest that daily neonatal stress produces varied alterations in spatial cognition at different life stages with a transient learning deficit at puberty preceding a more persistent and a progressive memory impairment through adulthood and into aging.

Synoviocytes protect cartilage from the effects of injury in vitro.

BACKGROUND: It is well documented that osteoarthritis (OA) can develop following traumatic joint injury and is the leading cause of lameness and subsequent wastage of equine athletes. Although much research of injury induced OA has focused on cartilage, OA is a disease that affects the whole joint organ. METHODS: In this study, we investigated the impact of synovial cells on the progression of an OA phenotype in injured articular cartilage. Injured and control cartilage were cultured in the presence of synoviocytes extracted from normal equine synovium. Synoviocytes and cartilage were evaluated for catabolic and anabolic gene expression. The cartilage was also evaluated histologically for loss of extracellular matrix molecules, chondrocyte cell death and chondrocyte cluster formation. RESULTS: The results indicate synoviocytes exert both positive and negative effects on injured cartilage, but ultimately protect injured cartilage from progressing toward an OA phenotype. Synoviocytes cultured in the presence of injured cartilage had significantly reduced expression of aggrecanase 1 and 2 (ADAMTS4 and 5), but also had increased expression of matrix metalloproteinase (MMP) -1 and reduced expression of tissue inhibitor of metalloproteinases 1 (TIMP-1). Injured cartilage cultured with synoviocytes had increased expression of both collagen type 2 and aggrecanase 2. Histologic examination of cartilage indicated that there was a protective effect of synoviocytes on injured cartilage by reducing the incidence of both focal cell loss and chondrocyte cluster formation, two major hallmarks of OA. CONCLUSIONS: These results support the importance of evaluating more than one synovial joint tissue when investigating injury induced OA.

Development of an in vitro model of injury-induced osteoarthritis in cartilage explants from adult horses through application of single-impact compressive overload.

OBJECTIVE: To develop an in vitro model of cartilage injury in full-thickness equine cartilage specimens that can be used to simulate in vivo disease and evaluate treatment efficacy. SAMPLE: 15 full-thickness cartilage explants from the trochlear ridges of the distal aspect of the femur from each of 6 adult horses that had died from reasons unrelated to the musculoskeletal system. PROCEDURES: To simulate injury, cartilage explants were subjected to single-impact uniaxial compression to 50%, 60%, 70%, or 80% strain at a rate of 100% strain/s. Other explants were left uninjured (control specimens). All specimens underwent a culture process for 28 days and were subsequently evaluated histologically for characteristics of injury and early stages of osteoarthritis, including articular surface damage, chondrocyte cell death, focal cell loss, chondrocyte cluster formation, and loss of the extracellular matrix molecules aggrecan and types I and II collagen. RESULTS: Compression to all degrees of strain induced some amount of pathological change typical of clinical osteoarthritis in horses; however, only compression to 60% strain induced significant changes morphologically and biochemically in the extracellular matrix. CONCLUSIONS AND CLINICAL RELEVANCE: The threshold strain necessary to model injury in full-thickness cartilage specimens from the trochlear ridges of the distal femur of adult horses was 60% strain at a rate of 100% strain/s. This in vitro model should facilitate study of pathophysiologic changes and therapeutic interventions for osteoarthritis.

Expansion of mesenchymal stem cells on fibrinogen-rich protein surfaces derived from blood plasma.

Mesenchymal stem cells (MSCs) are present in low density in bone marrow and culture expansion is necessary to obtain sufficient numbers for many proposed therapies. Researchers have characterized MSC growth on tissue culture plastic (TCP), although few studies have explored proliferation on other growth substrates. Using adult equine MSCs, we evaluated proliferation on fibrinogen-rich precipitate (FRP) surfaces created from blood plasma. When seeded at 1 × 10(4) cells/cm(2) and passaged five times over 10 days, MSCs on FRP in medium containing fibroblast growth factor 2 (FGF2) resulted in a ∼2.5-fold increase in cell yield relative to TCP. In FGF2-free medium, FRP stimulated a 10.4-fold increase in cell yield over TCP after 10 days, although control cultures maintained in FGF2 on TCP demonstrated that the stimulatory effect of FRP was not as lasting as that of FGF2. Chondrogenic cultures demonstrated that FRP did not affect differentiation. On TCP, MSCs seeded at 500 cells/cm(2) experienced a 4.6-fold increase in cell yield over cultures seeded at 1 × 10(4) cells/cm(2) following 10 days of expansion. In 500 cells/cm(2) cultures, FRP stimulating a two-fold increase in cell yield over TCP without affecting differentiation. Low-density FRP cultures showed a more even distribution of cells than TCP, suggesting that FRP may accelerate proliferation by reducing contact inhibition that slows proliferation. In addition, FRP appears capable of binding FGF2, as FRP surfaces pre-conditioned with FGF2 supported greater proliferation than FGF2-free cultures. Taken together, these factors indicate that substrates obtained from simple and inexpensive processing of blood enhance MSC proliferation and promote efficient coverage of expansion surfaces.

Induction of bone marrow mesenchymal stem cell chondrogenesis following short-term suspension culture.

The objective of this study was to evaluate mesenchymal stem cell (MSC) chondrogenesis following incubation in chondrogenic suspension cultures from which single cells were obtained. MSCs were maintained in suspension over a nonadherent surface for 3 days, dissociated into a suspension, and then evaluated for chondrogenesis in agarose in the presence or absence of transforming growth factor beta (TGFß). In a second experiment, MSCs from suspension culture were returned to monolayer expansion for 2 days prior to testing for chondrogenesis. In both cases, undifferentiated MSCs were evaluated as controls. Suspension culture alone did not stimulate chondrogenesis. Suspension followed by expansion stimulated a four- to ninefold increase in extracellular matrix (ECM) synthesis in TGFß-free cultures, a finding that was attributed to an increase in viable MSCs that secreted a proteoglycan-rich ECM. Gene expression of aggrecan and type II collagen increased with suspension culture, but decreased with postsuspension expansion. Therefore, stimulation of ECM synthesis without additional TGFß exposure could not be attributed to an enhancement of chondrogenesis with monolayer culture. ECM synthesis of suspension/expansion-conditioned MSCs without additional TGFß exposure was less than samples maintained in TGFß throughout the differentiation culture. Based on these findings, a better understanding of factors associated with early-stage chondrogenesis and MSC differentiation to a highly active phenotype may lead to improved methods for stimulating chondrogenesis during short-term culture.

Prostaglandin expression profile in hypoxic osteoblastic cells.

Conditions such as fracture and unloading have been shown to be associated with tissue and cellular hypoxia in bone. The effects of hypoxia on bone cell physiology and ultimately its impact on bone tissue repair and remodeling are not well understood. In this study, we investigated the role of hypoxia on prostaglandin release from osteoblastic cells cultured in 2% (hypoxia), 5% (potentially cellular normoxia), and 21% (normoxia for standard cell culture conditions) oxygen for up to 24 h. We quantified the effects of reduced oxygen tension on the release of prostaglandin (PG)E(2), PGF(2alpha), PGD(2), and PGI(2). The mechanism by which hypoxia increases PG production was investigated by examining the various regulatory components of the PG biosynthetic pathway. Our data show that PGE(2) levels alone are significantly elevated under hypoxic conditions. Also, we show that cyclooxygenase (COX)-1 and COX-2 play an important role in hypoxia-induced PGE(2) production, possibly via a mechanism involving changes in their respective activity levels under low oxygen conditions. The effect of hypoxia on PGE(2) levels was mimicked by dimethyloxaloglycine, a known activator of the HIF pathway. In addition, we confirmed that HIF-1alpha was stabilized in osteoblastic cells under hypoxia. Taken together these data suggest a role for the HIF pathway in regulation of PGE(2) levels under hypoxic conditions. Previous studies have detected release of prostaglandins from areas of damaged bone, such as a fracture site, and our data may contribute to an understanding of how this release is regulated.

HIF-1alpha regulates hypoxia-induced EP1 expression in osteoblastic cells.

Changes in regional oxygen tension that occur during skeletal development and fracture stimulate local bone cell activity to regulate bone formation, maintenance, and repair. The adaptive responses of bone cells to hypoxia are only beginning to be understood. The transcription factor hypoxia-inducible factor-1alpha (HIF-1alpha) is activated under hypoxia and promotes expression of genes required for adaptation and cell survival, and also regulates both bone development and fracture repair. We have previously demonstrated that hypoxic osteoblasts increase PGE(2) release and expression of the PGE(2) receptor EP1. In the present studies, we investigated the impact of altered HIF-1alpha activity and expression on EP1 expression in osteoblasts. HIF-1alpha stabilization was induced in cells cultured in 21% oxygen by treatment with dimethyloxaloglycine (DMOG) or siRNA targeted against PHD2. To implicate HIF-1alpha in hypoxia-induced EP1 expression, osteoblastic cells were treated with siRNA targeted against HIF-1alpha prior to exposure to hypoxia. EP1 expression was significantly increased in cells cultured in 21% oxygen with DMOG or PHD2 siRNA treatment compared to controls. Hypoxia responsive element (HRE) activation in hypoxia was attenuated in cells treated with HIF-1alpha siRNA compared to controls, indicating HIF-1alpha as the functional HIF-alpha isoform in this system. Furthermore, hypoxic cells treated with HIF-1alpha siRNA demonstrated reduced EP1 expression in hypoxia compared to controls. Inhibition of SAPK/JNK activity significantly reduced hypoxia-induced EP1 expression but had no impact on HIF-1alpha expression or activity. These data strongly implicate a role for HIF-1alpha in hypoxia-induced EP1 expression and may provide important insight into the mechanisms by which HIF-1alpha regulates bone development and fracture repair.

Personality in domestic cats.

Personality ratings of 196 cats were made by their owners using a 5-point Likert scale anchored by 1: not at all and 5: a great deal with 12 items: timid, friendly, curious, sociable, obedient, clever, protective, active, independent, aggressive, bad-tempered, and emotional. A principal components analysis with varimax rotation identified three intepretable components. Component I had high loadings by active, clever, curious, and sociable. Component II had high loadings by emotional, friendly, and protective, Component III by aggressive and bad-tempered, and Component IV by timid. Sex was not associated with any component, but age showed a weak negative correlation with Component I. Older animals were rated less social and curious than younger animals.

Hypoxia regulates PGE(2) release and EP1 receptor expression in osteoblastic cells.

Changes in regional O(2) tension that occur during fracture and skeletal unloading may stimulate local bone cell activity and ultimately regulate bone maintenance and repair. The mechanisms by which bone cells sense and respond to changes in O(2) tension are unclear. In this study we investigated the effects of low O(2) on activation of the hypoxia response element (HRE), prostaglandin E(2) (PGE(2)) production, PGE(2) receptor (EP) expression and proliferation in MC3T3-E1 osteoblastic cells. Cells were cultured for up to 72 h in 2% O(2) (considered hypoxic), 5% O(2) (in the range of normal O(2) tension in vivo) or 21% O(2) (commonly used for cell culture). Cells cultured in 2% O(2) showed activation of the HRE, increased PGE(2) release, increased EP1 expression, and reduced cell proliferation compared to cells grown at 21% O(2). Similarly, cells cultured in 5% O(2) showed increased expression of EP1 and a trend toward a decrease in proliferation, but no activation of the HRE or increase in PGE(2) levels. Expression of EP2, EP3 and EP4 were not affected by O(2) tension. The differences in EP receptor profile observed in cells grown at 5% compared to 21% O(2) suggest that bone cell phenotype may be altered under routine cell culture conditions. Furthermore, our data suggest that hypoxia-dependent PGE(2) production and EP1 expression in bone cells may play a role in bone remodeling and repair in regions of compromised or damaged bone, where O(2) tension is low.

Association between findings on palmarodorsal radiographic images and detection of a fracture in the proximal sesamoid bones of forelimbs obtained from cadavers of racing Thoroughbreds.

OBJECTIVE: To determine the distribution for limbs and bones in horses with fractures of the proximal sesamoid bones and relationships with findings on palmarodorsal radiographic images. SAMPLE POPULATION: Proximal sesamoid bones obtained from both forelimbs of cadavers of 328 racing Thoroughbreds. PROCEDURE: Osteophytes; large vascular channels; and fracture location, orientation, configuration, and margin distinctness were categorized by use of high-detail contact palmarodorsal radiographs. Distributions of findings were determined. Relationships between radiographic findings and fracture characteristics were examined by use of chi2 and logistic regression techniques. RESULTS: Fractures were detected in 136 (41.5%) horses. Biaxial fractures were evident in 109 (80%) horses with a fracture. Osteophytes and large vascular channels were evident in 266 (81%) and 325 (99%) horses, respectively. Medial bones typically had complete transverse or split transverse simple fractures, indistinct fracture margins, > 1 vascular channel that was > 1 mm in width, and osteophytes in abaxial wing and basilar middle or basilar abaxial locations. Lateral bones typically had an oblique fracture and distinct fracture margins. Odds of proximal sesamoid bone fracture were approximately 2 to 5 times higher in bones without radiographic evidence of osteophytes or large vascular channels, respectively. CONCLUSIONS AND CLINICAL RELEVANCE: Biaxial fractures of proximal sesamoid bones were common in cadavers of racing Thoroughbreds. Differences between medial and lateral bones for characteristics associated with fracture may relate to differences in fracture pathogeneses for these bones. Osteophytes and vascular channels were common findings; however, fractures were less likely to occur in bones with these features.