Reduced Levels of Total Leukocytes and Neutrophils in Norwegian Cattle Selected for Decreased Mastitis Incidence

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Reduced Levels of Total Leukocytes and Neutrophils in Norwegian Cattle Selected for Decreased Mastitis Incidence

S. Kulberg^*, A. K. Storset^*, B. Heringstad and H. J. S. Larsen^*

^* Department of Pharmacology, Microbiology, and Food Hygiene, The Norwegian School of Veterinary Science, N-0033 Oslo
Department of Animal Science, Agricultural University of Norway, N-1432 Ås

Corresponding author:
Siri Kulberg; e-mail:
siri.kulberg{at}veths.no.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Two groups of Norwegian Cattle showing significant genetic differencesin clinical mastitis susceptibility were examined for hematologicalchanges at three stages of lactation. Blood samples were takenfrom 91 healthy Norwegian Cattle cows and heifers belongingeither to a high protein yield group or to a low clinical mastitisgroup and analyzed for hematological properties and serum cortisollevels at three stages of lactation. All animals were free ofintramammary infections at the time of sampling.

All cows had increased total white blood cells, neutrophils,and neutrophil/lymphocyte ratio as parturition approached, withpeak levels at parturition. Cows selected for low clinical mastitishad lower levels of total white blood cells and neutrophilscompared with cows selected for high protein yield throughoutall three periods. The difference was significant prepartum.Cows from the low clinical mastitis group also had lower neutrophil/lymphocyteratios and lower serum cortisol levels than those in the highprotein yield group. A significant positive correlation wasfound between cortisol and total white blood cells and neutrophils,respectively.

We conclude that selection for lower mastitis incidence in thelow clinical mastitis group is associated with a significantdecrease in total white blood cells and neutrophils in bloodprepartum. Results from the present study, and the genetic differencein mastitis incidence observed in the groups, indicates thatincreased leukocyte mobilization at certain stages of lactationmay be associated with increased susceptibility to mastitis.

Abbreviation key: HPY = High protein yield, LCM = low clinical mastitis, N/L ratio = neutrophil/lymphocyte ratio, NRF = Norwegian Cattle

Key Words: dairy cow • selected cattle group • parturition • leukocyte

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

During the periparturient period, dairy cows are exposed toconsiderable hormonal changes and sudden onset of milk production,which impairs immune defense mechanisms (Kehrli et al., 1989;Mallard et al., 1998). Immunological dysfunctions have beenobserved from approximately 3 wk prepartum until 3 wk postpartum(Kehrli et al., 1989; Mallard et al., 1998; Kimura et al., 1999).Several in vitro experiments carried out in cattle during thesame periparturient period have revealed decreased neutrophilfunction (Roth and Kaeberle, 1982; Detilleux et al., 1994; Kimura et al., 1999).

Despite the immunosuppression, increasing numbers of total whiteblood cells are found in the peripheral blood of periparturientanimals, mainly due to a rise in neutrophil concentration. Peakvalues are observed at parturition, but levels decline shortlyafter and reach basal conditions within 2 wk postpartum (Detilleux et al., 1995;Kimura et al., 1999; Klinkon and Zadnik, 1999).

Neutrophils are crucial in protecting the body against invadingpathogens. As a first group of defense they migrate rapidlyinto tissue where they phagocytose and kill invaders at sitesof inflammation. Physiologically high periparturient blood concentrationsof glucocorticoids have been suggested as an explanation forthe increased neutrophil count around parturition (Burton et al., 1995;Lee and Kehrli, 1998; Kehrli et al., 1999).

Cortisol is a well-accepted indicator for stress in animalsand man. A release of adrenocorticotropic hormone from the pituitarygland occurs in late pregnancy. Adrenocorticotropic hormonesinduce synthesis and secretion of glucocorticoids from the adrenalcortex. It is well-known that glucocorticoids have an immunosuppressiveeffect (Kehrli et al., 1999). Although the exact mechanism isnot completely understood, it is believed that glucocorticoidsincrease the bone marrow output of neutrophils and induces anenzymatic cleavage of L-selectin on the neutrophil surface.Reduced expression of L-selectin shifts the neutrophil populationfrom the marginating pool to the peripheral circulation, andresults in a larger circulating pool of neutrophils less capableof migrating towards sites of inflammation. Consequently animalsbecome more susceptible to infections (Roth and Kaeberle, 1982;Burton et al., 1995; Lee and Kehrli, 1998).

The unfavorable genetic correlation between mastitis and milkyield (Heringstad et al., 2000), implies that single trait selectionfor increased milk production is expected to increase susceptibilityto mastitis. In 1989, GENO Breeding and A. I. Association andDepartment of Animal Science, Agricultural University of Norwaystarted a dairy cattle selection experiment that includes twoselection groups of Norwegian Cattle (NRF); one high proteinyield (HPY) group and one low clinical mastitis (LCM) group.More than 10 years of selection have resulted in two groupsof cows with genetically different levels of susceptibilityto clinical mastitis. The cows from this experiment representa unique resource for studies of the underlying mechanisms causinga realized reduction in mastitis frequency among animals selectedfor improved health.

The aim of the present study was to observe the effect of differentlactation stages on serum cortisol levels and hematologicalproperties, especially neutrophil count, in the two groups ofNRF selected for high protein yield or low clinical mastitis,respectively. We hypothesize that there might be differencesin total white blood cells and neutrophil counts between thetwo groups.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Selection Experiment
The two groups of cows (HPY and LCM) used in this study werefrom a Norwegian dairy cattle selection experiment. The experimentstarted in 1989 and included eight herds (seven agriculturalschools and one state farm) in different parts of Norway. Eachherd was divided in two groups with approximately the same numberof cows in each group. The LCM and HPY group was establishedbased on NRF cows selected for high milk yield from a previousselection experiment. Proven sires from the active breedingprogram of GENO Breeding and A. I. Associations were used assires in the experiment. Each year, two to four of the highest-rankingsires with respect to EBV for protein yield or mastitis resistance,respectively, were selected among the 120 to 130 NRF test bullsthat are progeny tested annually. This implies single traitselection of sires that were preselected for NRF breeding objective.NRF has been selected for a broad breeding objective, with increasingemphasize on functional traits like health and fertility overthe last 20 years, and the current breeding objective resultsin genetic improvement for both protein yield and mastitis resistance(Heringstad et al., 2001).

Cows in the HPY group were mated to the two to four highestranking proven sires with regard to protein yield each year,and cows in the LCM group were mated to the two to four bestproven sires for mastitis resistance each year.

All cows present in the herd when the selection experiment startedthat were mated with one of the defined sires and produced adaughter that made a first lactation record of mastitis and/orprotein yield were defined as cow-generation 0, their daughterswere defined as cow generation 1, and so on. After three cowgenerations, the genetic difference between HPY and LCM cowswas equivalent to 15.4 kg protein (305 d lactation yield, kgprotein) and 8.6% clinical mastitis (B. Heringstad, 2002, unpublished).These estimated genetic differences were based on EBV for cowsfrom linear animal model analysis of data for the total NRFpopulation from 1978 to 1999. The mean EBV for the 34 siresused in the HPY group and the 28 sires used in the LCM groupin the period from 1989 to 1998 was 0.0179 and –0.0727for clinical mastitis and 24.36 and 2.83 for protein yield,respectively (B. Heringstad, 2002, unpublished).

Animals and Blood Sampling
Due to practical reasons, the four herds closest to the NorwegianSchool of Veterinary Science were chosen for this study (Buskerud,Jønsberg, Kalnes, and Mære). These herds do notdiffer from the other four herds except in location. Animalswere chosen for sampling according to their expected calvingdates, and the number of animals sampled in each herd accordingto the size of the herd. Animals, both primiparous and multiparous,with overlapping calving dates were chosen. An equal numberof animals were sampled from each selection group.

Blood samples were taken from the jugular vein 2 wk prior tocalving, as soon as possible after calving, and 1 mo after calving.Milk samples were collected from all four quarters as soon aspossible after calving and 1 mo after calving. Because of thedistances and the number of animals sampled, local veterinarianstook most samples.

On each occasion, a 10 ml sample of blood was withdrawn intoVenoject glass tubes containing EDTA as anticoagulant (TerumoEurope N.V., Leuven, Belgium) for hematological analysis, whileanother 10 ml sample was withdrawn into Venoject glass tubeswith no anticoagulant (Terumo) to provide serum samples. Thehematological analyses were performed shortly after sampling.The serum samples were stored frozen at –20°C untilanalyzed.

Because several persons were involved in the sampling procedure,and predicting calving dates accurately is quite difficult,some of the samples were taken too late or too early in relationto the actual calving date or were not taken at all. In addition,some of the animals were culled during the sampling period.Finally, a total of 121 animals were sampled from the four herds(Table 1). 16 animals were sampled once, 26 animals were sampledtwice, and 81 animals were sampled three times. There were nomajor differences in average age of the cows sampled, or inmean sampling day pre- or postpartum (Table 2).

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Table 1. Total number of samples and individuals in the study, number of excluded samples, and total number of samples and individuals finally included from the low clinical mastitis (LCM) group and high protein yield (HPY) group.

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Table 2. Number of samples, average (SD) age of sampled animals, and average (SD) days pre-/postpartum each sample was collected for cows from the low clinical mastitis (LCM) group and high protein yield (HPY) group.

The intervals studied were: (1) prepartum - not earlier than28 and not later than 14 d prepartum; (2) parturition - within5 d postpartum; and (3) peak lactation - not earlier than 28and not later than 60 d postpartum. All cows sampled outsidethese periods were excluded. Milk samples were cultured on bloodagar plates using standard methodology (State Veterinary Laboratories of Norway, 1993)at the National Veterinary Institute, Oslo. The culturing wasperformed to identify individuals with pathogens indicativeof clinical mastitis in their milk samples. If pathogens weredetected in the cultured milk, the matching blood sample wasdiscarded from the study.

A total of 85 cows were sampled outside the sampling periodsand excluded (Table 1). There was no discrepancy between thegroups. A total of 51 samples were excluded due to indicationsof udder infection (Table 1). The discrepancy seen between thegroups were due to different numbers of animals sampled fromeach group. Additionally, some of the cows with indicationsof udder infection had a SCC within normal ranges, and it isquestionable if these samples represent true udder infections.However, these samples were excluded the same way as sampleswith both pathogens in the milk and an increased SCC. In theLCM group, ten of these samples were found, compared with onlyfour in the HPY group.

At the end, 91 cows were included in the study (Table 1), andmore than 75% of these were from cow-generation 2 and 3; 4,7, and 12 cows were from cow-generation 0, 1, and 4, respectively.The mean EBV for clinical mastitis for sires of the 53 LCM cowsand sires of the 38 HPY cows were –0.004 and –0.079,respectively, a difference equivalent to 7.5% clinical mastitis.The corresponding mean EBV for protein yield (305 d lactationyield, kg protein) were 3.35 and 26.19 for sires of the LCMand HPY cows.

Leukocyte Counting and Cortisol Analysis
Haematological analyses were performed at the Central Laboratory,Norwegian School of Veterinary Science, Oslo. Total white bloodcells (x 10⁶ /ml) and differential counts (x 10⁶ /ml) of monocytes,lymphocytes, neutrophils, eosinophils, and basophils, were calculatedusing a Technicon ADVIA 120 (Technicon Industrial Systems, Tarrytown,NY).

Serum cortisol levels were analyzed by radioimmunoassay (Simensen et al., 1978)at the Department of Reproductive Physiology and Pathology,Norwegian School of Veterinary Science, Oslo.

Statistical Analysis
All results are expressed as mean values with 95% confidenceintervals constructed using the Student procedure (Altmann,1991). Standard deviation was used as the index for dispersion.Differences between groups were considered statistically significantif the P-value was less than or equal to a level of 5%.

P-values were adjusted for multi-significance using the Bonferronicorrection. An ANOVA expectation component model was used tocompare groups, when variables could be assumed normally distributed(Altmann, 1991).

Assumption of normality was rejected for neutrophils and cortisol.In these cases, the Wilcoxon two-sample test was used (Lehmann,1975).

The Pearson linear correlation analysis was used to study theconnection pattern between the included variables (Altmann,1991). All 169 single samples from the 91 animals included wereused in the correlation analysis. The residual correlation forthe four parameters, total white blood cells, neutrophils, theneutrophil/lymphocyte (N/L) ratio, and cortisol was calculatedby correction for animal group and stage of lactation.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

Haematology
In the time from the prepartum stage until parturition, significantincreasing levels of total white blood cells (Figure 1) wereseen in the LCM group, and significant increasing levels ofneutrophils (Figure 2) were found in both groups. A rise inthe N/L ratio (Figure 3) was also observed between the two stages.Peak values of all three parameters were found at parturition.The rise in total white blood cells was mainly due to increasingneutrophil numbers. A significant decline in total white bloodcells was observed in the LCM group, and a significant declinein neutrophil levels was seen in both groups postpartum, reachinglevels similar to those observed prepartum. The N/L ratio alsodeclined postpartum.

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Figure 1. Mean (with 95% confidence intervals) numbers of total white blood cells in peripheral blood of the high protein yield group (HPY) cows and the low clinical mastitis group (LCM) cows at three stages of lactation.

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Figure 2. Mean (with 95% confidence intervals) numbers of neutrophils in peripheral blood of the high protein yield group (HPY) cows and the low clinical mastitis group (LCM) cows at three stages of lactation.

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Figure 3. Mean (with 95% confidence intervals) neutrophil/lymphocyte ratio (N/L ratio) in peripheral blood of the high protein yield group (HPY) cows and the low clinical mastitis group (LCM) cows at three stages of lactation.

Leukocytosis was found at all stages of lactation in the HPYanimals, neutrophilia only at parturition. Leukocytosis andneutrophilia were found at parturition in the LCM animals. Throughoutall stages of lactation, the HPY cows showed higher concentrationsof total white blood cells and neutrophils, and a higher N/Lratio than the LCM cows. The difference in total white bloodcell concentration (P $≤$ 0.02), neutrophil concentration (P $≤$ 0.002),and the N/L ratio (P $≤$ 0.01) was significant prepartum, but notat parturition nor at peak lactation.

As for the other leukocytes, monocyte and basophil levels increasedduring parturition, whereas lymphocyte and eosinophil levelsdecreased. There were no significant differences between thegroups.

Significant, positive correlations were found between totalwhite blood cells and neutrophils (r = 0.81, P < 0.001),total white blood cells and N/L ratio (r = 0.39, P < 0.001),and neutrophils and N/L ratio (r = 0.78, P < 0.001). Theresults shown are correlations corrected for differences dueto genetic group and stage of lactation.

Cortisol
Serum cortisol levels (Figure 4) increased as parturition approached,with peak levels at parturition. Slightly decreasing levelswere found postpartum. Throughout all three periods, serum cortisollevels were higher in the HPY group than in the LCM group, althoughnot significantly.

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Figure 4. Mean (with 95% confidence intervals) serum cortisol levels in peripheral blood of the high protein yield group (HPY) cows and the low clinical mastitis group (LCM) cows at three stages of lactation.

Significant positive correlations were found between total whiteblood cells and cortisol (r = 0.24, P < 0.01), and neutrophilsand cortisol (r = 0.29, P < 0.001). The results are correlationscorrected for differences due to genetic group and stage oflactation.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

In the present study, increasing numbers of total white bloodcells and neutrophils were observed in the peripheral bloodof periparturient cows prior to parturition. The total whiteblood cell rise was mainly caused by an increase in the numberof neutrophils. These results are consistent with findings inperiparturient cattle described by other authors (Detilleux et al., 1994;Kimura et al., 1999; Klinkon and Zadnik, 1999). The presentstudy detected higher blood neutrophil concentrations in HPYanimals compared to LCM animals during all stages of lactationinvestigated. However, the difference was only significant prepartum.In a study on Holstein cows selected for high or average milkproduction, significantly higher numbers of neutrophils werefound in the peripheral circulation of high milk producers thanin average milk producers during the periparturient period (Detilleux et al., 1995).Our study observed higher neutrophil numbers in HPY cows, whichshow differences in genetic level for protein yield comparedwith LCM cows.

The N/L ratio in both selection groups increased as parturitionapproached. In the HPY group, the N/L ratio was higher thanin the LCM group on all sampling occasions. The difference wassignificant prepartum. An increased N/L ratio has been describedpreviously in animals under conditions of stress (McGlone et al., 1993;Stull and Rodiek, 2000).

Serum cortisol levels were higher in the HPY group than theLCM group at all stages of lactation. Levels increased up toparturition, where they reached their peak. After parturition,the cortisol concentration slowly decreased.

Experimental injections with synthetic glucocorticoids to createartificial stress similar to the stress seen in the periparturientperiod induced marked neutrophilia and down-regulation of L-selectinon neutrophil membranes. The neutrophils became less able tomigrate and the susceptibility to infections increased (Burton et al., 1995;Nakagawa et al., 1999). The present study detected a significantpositive correlation between neutrophils and the plasma cortisollevel in the two groups.

The periparturient period induces physiological stress in cattle.It has been shown that transport-induced stress in differentspecies leads to elevated cortisol blood concentrations, increasesin total white blood cell and neutrophil levels, and an elevatedN/L ratio (Dalin et al., 1993; McGlone et al., 1993; Stull and Rodiek, 2000).Animals highly susceptible to stress would almost certainlyproduce higher levels of cortisol in the periparturient periodthan less susceptible individuals, and would as a result havehigher total white blood cells and neutrophil concentrationsin blood than the less susceptible animals.

Different basal cortisol levels in blood have been observedamong breeds with different susceptibility to stress (Zavy et al., 1992;Garcia-Belenguer et al., 1996), suggesting a genetic effectof this parameter. This results in permanently higher physiologicaltotal white blood cell and neutrophil numbers. On the otherhand, cattle selected for fighting and dominance ability, althoughhaving the same basal cortisol levels as other breeds, wereless fearful to surprising-effect tests, and experienced a lesspronounced rise in cortisol levels, than other breeds, whensubjected to stress (Plusquellec and Bouissou, 2001).

Whether the rise in cortisol level is permanently present, oronly under temporary conditions of stress, it nevertheless mayresult in neutrophils being less capable of migration and phagocytosis,and consequently in animals with higher susceptibility to infectiousdiseases.

In the present study, increases in total white blood cells,neutrophils and the N/L ratio were significantly higher in theHPY group than in the LCM group prepartum.

Hematological changes prepartum are stress related, previouslyconnected with the periparturient period. It is not possibleto conclude solely based on this investigation whether the changesobserved prepartum are permanent or if they are induced by theperiparturient period. However, it is reasonable to suggestthat the changes observed are either due to periparturient stress,and that the HPY group may be more affected by this than theLCM group, or that the differences may be permanent and dueto higher basal cortisol levels in the HPY group. A differencein leukocyte recruitment between the groups is also a possibilityand may represent a stronger inflammatory response upon localstimulation in the HPY group.

CONCLUSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

The LCM group of NRF showed significantly lower total whiteblood cell and neutrophil levels in blood prepartum than theHPY group. The difference was also present at parturition andat peak lactation, but not to a significant degree. It is reasonableto postulate that the difference is genetically predisposed,possibly caused by higher stress susceptibility, or higher leukocyterecruitment due to stronger inflammatory responses in the HPYgroup. This may partly explain the difference in mastitis susceptibilitybetween these groups.

Further studies are needed to draw a firm conclusion. Analysisof neutrophil counts and baseline cortisol levels in the groupsat other stages of lactation, will also reveal possible differenceshere, or support the hypothesis that the differences are relatedto the periods investigated in this study.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

The authors would like to thank the herd employees at the agriculturalschools: Buskerud, Jønsberg, Kalnes, and Mære forassistance with animal handling and blood sampling, Stig Larsenfor statistical assistance, StaÅle Sviland for the culturingof milk samples, and Ellen Dahl for assistance with cortisolanalysis.

Received for publication October 9, 2001. Accepted for publication June 7, 2002.

REFERENCES

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INTRODUCTION
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RESULTS
DISCUSSION
CONCLUSION
ACKNOWLEDGEMENTS
REFERENCES

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Lee, E., and M. E. Kehrli. 1998. Expression of adhesion molecules on neutrophils of periparturient cows and neonatal calves. Am. J. Vet. Res. 59:37–43.[Medline]

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Plusquellec, P., and M. Bouissou. 2001. Behavioural characteristics of two dairy breeds of cows selected (Herens) or not (Brune des Alpes) for fighting and dominance ability. Appl. Anim. Behav. Sci. 72:1–21.[Medline]

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