Morada Nova lambs’ meat production potential description through morphometric evaluation

ABSTRACT: Morada Nova breed has a low effective herd, and its white variety is in risk of extinction. The selection of individuals based on breed standard without correlation with productive aptitude is predominant today. We believe that the best way to rescue this valuable genetic resource is to describe its productive potential for commercial use. Thus, this study described the meat production potential of Morada Nova lambs through morphological and zoometric data, performance and carcass characteristics. Twenty-four non-castrated male lambs from two genetic groups were used: Morada Nova red (MNR) and crossbreed Morada Nova (red x Morada Nova white-MNF1) distributed in a completely randomized design. Univariate and multivariate analysis were used. The yields of commercial cuts and the physicochemical characteristics and qualitative measurements of the carcass were similar between the genetic groups. Seven of the 28 characteristics of the carcass were greater in MNF1 lambs. The chest height, rump height and anamorphosis index showed to be important variables in the choice of MN lambs with meat production potential. Based on factor and hierarchical cluster analysis, the Morada Nova beef morphometric index (MNBMI) was created. Both of groups have high thoracic development, ability to produce meat, weight gain, feeding efficiency and breathing capacity, infusing greater rusticity and adaptability; however, the application and validation of the developed index showed superiority for meat production in the crossed lambs. Thus, the MNF1 lambs are a sustainable option for sheep production in drylands.


INTRODUCTION
The Brazilian semi-arid region has traditionally raised sheep with a total of 68.5% of the national effective herd [Brazilian Institute of Geography and Statistics (IBGE, 2017)], with the potential for semi-intensive exploitation in sheep meat farming mainly using native breeds and their crosses to increase meat production (LOBO, 2019).Among these breeds, Morada Nova (M N ) is one of the main genetic resources of hair sheep in the Brazilian semi-arid region, being recognized for its resistance to gastrointestinal endoparasites (TOSCANO et al., 2019), adaptability to the thermal environment (COSTA, et al., 2018), potential as a maternal breed in terminal crossbreeding (LANDIM, et al., 2021), fertility without seasonal influence (MOURA et al., 2019), and carcasses with fatty acid profiles with potential benefit to human health (LAGE et al., 2020).Certainly, on a scientific basis, the Brazilian Agricultural Research Corporation (Embrapa Goats & Sheep) recommended carrying out a reproductive Ciência Rural, v.53, n.8, 2023.Alves et al. and productive survey of the breed in order to encourage its sustainable inclusion in Brazilian sheep production systems (LOBO, 2019).
The Brazilian Association of Sheep Breeders (Associação Brasileira de Criadores de Ovinos -ARCO) recognizes the genetic record of two genetic groups of the M N breed: red (M NR ) and white hair, and uses as genealogical control criteria, morphological characteristics and breed standard in the registration of animals.These traits are also promoted at events such as exhibitions, auctions and the animal trade of the breed.Empirically, Brazilian sheep breeders have judged the white variety as "poorly adapted" whereas the red variety is considered "too small for meat production".These kinds of claims are contradicted by the studies cited on the breed.Despite the genetic differentiation existing among the varieties of the M N breed, (FERREIRA, et al., 2014), there is population fragility due to extinction risk, low effective number of the herd and increased inbreeding rate caused by the indiscriminate introduction of exotic breeds (NUNES et al., 2020).
The body biometrics is a simple tool applied in commercial herds and/or in nuclei to preserve genetic resources in order to assist in zootechnical characteristic studies.With the association of these measures from different body regions, it is possible to generate zoometrical indices which identify the aptitude and productive potential of the animals, defining the breeding standard and ability for commercial exploitation (GUIMARÃES, 2018), in addition to relating these indicators to the performance and carcass characteristics.At the same time, this description is an essential step in the recovery of a genetic resource [Commission on Genetic Resources for Food and Agriculture Assessments (FAO, 2012)].
Brazilian sheep farmers have empirically implemented crossbreeding of Morada Nova varieties, but the adequate characterization of those is weak or inexistent.This lack of scientific information precludes further conclusions about this native breed and their crosses.Considering the risk status of the breed, the lack of knowledge about the productive potential of meat in the breed and its varieties, the empirical management given in the selection and commercialization of animals and the basic knowledge of breeders about the morphological evaluation of animals; this study described the meat production potential of M NR and crossed M NR and white (M NF1 ) lambs using morphological and zoometric data, performance and carcass characteristics.

Experiment site
The study was conducted at the Research Center for Nutrition of Small Ruminants at the Experimental Farm of the State University Vale do Acaraú (UVA), located in Sobral, Ceará, Brazil (3° 36" S, 40° 18" W and 56 m asl).The region's climate is Bsh (B -Dry, S -Semi-arid, low h-latitude) according to the Köppen Climate Classification (ALVARES et al., 2013).

Animals, experimental design and diet
A total of 24 non-castrated male lambs from two genetic groups were used (12 lambs per group): Morada Nova red (M NR ) and F 1 Morada Nova red x Morada Nova white (M NF1; ½ M NR ½ M NW ) with an average initial body weight of 16.9 ± 3.43 kg and an average age of four months distributed in a completely randomized design.The use of pure M NW lambs in this study was not possible due to the small population of this genetic group considered to be in extinction (NUNES et al., 2020).The lambs were fed with a standard isoproteic and isoenergetic diet during the experimental period according to the nutritional requirements recommended by the National Research Council (NRC, 2007) for lambs of late maturity in the finishing phase with a predicted weight gain of 200 g day -1 .Water and mineral salt were supplied ad libitum.

Measurements and morphometric indices in vivo
Morphometry was measured in the last week prior to slaughtering the animals with a tape measure and a biometric rod adapted according to (ARAÚJO, et al., 2014;BIANCHINI et al., 2006;REZENDE et al., 2014).The lambs were kept in the correct upright position on a horizontal concrete floor without slope during the measurements.The withers height (W H ), rump height (R H ), chest height (C H ), thoracic depth (T D ), chest width (C W ), body length (B L ), and chest girth (C G ) were measured.The morphometric measurements were combined to elaborate conformation indices, aptitudes and productive and genetic potential according to (CONTRERAS et al., 2011;RAMOS, I. O. et al., 2019;SILVA-JARQUIN et al., 2019).The indices with their respective equations were: 1) Body index (B I ): body length divided by thoracic perimeter (longiline animals have B I > 0.90; medium-length or medigline 0.86 ≤ B I ≤ 0.88; and short-length or brevigline animals B I < 0.85); 2) Relative body index (R BI ): ratio of body length to withers height; 3) Thoracic perimeter relation index (T PRI ): chest circumference divided by withers height; 4) Anamorphosis index (A I ): thoracic perimeter squared divided by withers height, multiplied by 100; 5) Body capacity index "1" (B CI "1"): corresponding to the quotient between weight and body length; 6) Body capacity index "2" (B CI "2"): corresponding to the quotient between weight and thoracic perimeter; 7) Withers-rump relation index (W-R RI ): withers height divided by rump height; in which: values equal to 1 describe an animal with thoracic and pelvic limbs of the same height (balance); 8) Body side index (B SI ): withers height divided by body length, multiplied by 100.This index provides an understanding of the general shape of the animal's body, meaning if it is long and leggy or short, also indicating production capacity; and a last index was proposed, 9) Thoracic body index (T BI ): (body length / withers height) ÷ (withers height / chest depth) x 100.

Slaughter and carcass characteristics
The lambs were slaughtered at 210 (± 8 days) of age.The animals were fasted on a solid diet for 16 hours and then weighed prior to slaughter.The slaughter procedure was carried out following the rules of the Industrial and Sanitary Inspection of Products of Animal Origin, that including animal welfare protocols (RIISPOA -Regulamento da Inspeção Industrial e Sanitária de Produtos de Origem Animal), (BRASIL, 2017).Then, the noncarcass components were eviscerated and weighed.After obtaining the carcasses, the pH 0 hour after slaughter was measured using a portable digital pH meter (Testo 205, São Paulo, Brazil) provided with a glass electrode, calibrated with pH 7.0 and pH buffer solution 4.0.The carcasses were identified and weighed to determine the hot carcass weight (H CW ).The empty body weight (E BW ) was determined according to SILVA SOBRINHO et al., (2005).Then, the carcasses were packed in plastic bags and sent to a cold chamber (4°C for 24 hours).After this period, the cold carcass was weighed and the pH 24 hours after slaughter was determined.The cooling weight loss [C WL , %) = (H CW -C CW ) × 100/H CW ], in which: H CW = hot carcass weight (kg) and C CW = cold carcass weight (kg).The cuts and carcass composition were longitudinally sectioned using a cold saw (G Paniz SF248, Rio Grande do Sul, Brazil), and the left half carcasses were divided into six commercial cuts: leg, shoulder, rib, breast, neck, and loin.These cuts were individually weighed to determine their respective yields (%).In addition, subcutaneous fat thickness (S FT ) was measured using a 200 mm digital caliper (ZAAS-01.0013,São Paulo, Brazil).Finally, the loin eye area of the Longissimus lumborum (L L ) muscle exposed on the 12 th thoracic rib was calculated using the geometric method (CEZAR & SOUSA, 2018).

Qualitative analysis of the carcass
Conformation, finishing and evaluation of perirenal fat were determined by visually evaluating the carcass according to the methodology described by CEZAR & SOUSA (2018).For conformation, a score of 1 was given for poor conformation to 5 as very good according to the musculature and adipose tissue deposition in relation to the skeleton.Meanwhile, finishing was classified into five categories (score 1 = very thin and 5 = very fat) according to the subcutaneous fat amount and distribution in the chilled carcass.A score of 1 to 3 was assigned for perirenal fat assessment according to the amount of fat in the abdominal cavity around the kidneys (1 = left kidney without fat cover; 2 = fully coated left kidney and the right partially; and 3 = both are covered by a thick layer of fat).

Morphometric measurements and carcass indexes
The morphometric measurements were obtained from the carcass and were carried out as recommended by CEZAR & SOUSA (2018).The morphometric measurements were: carcass external length (C EL ), carcass chest girth (C CG ), leg length (L L ), leg girth (L G ), arm length (A L ), arm girth (A G ), carcass internal length (C IL ), carcass internal width (C IW ).The carcass indexes and their equations were: 1) Arm compactness index (A CI ): the quotient between the shoulder weight and the arm length; 2) Leg compactness index (L CI ): relationship between the shank weight and the leg length; 3) Carcass compactness index (C CI ): the relationship between the cold carcass weight and the internal carcass length; and 4) Carcass economic index (C EI ): [(Hot carcass yield * 0.25 + Loin eye area * 0.15 + Leg yield * 0.1 + Loin yield × 0.1 + Subcutaneous fat thickness × 0.1 + Carcass compactness index × 0.09 + Conformation × 0.05 + finish × 0.05) / (Cooling weight loss × 0.05 + age × 0.06)] × 100.This last index was proposed based on commercial values for the Brazilian sheep meat market.

Data analysis
All analyzes were processed and analyzed using the SPSS ® software statistical package (IBM CORP., 2013).All continuous variables met the assumptions of the analysis of variance (ANOVA) on univariate normality by the Shapiro-Wilk test (P > 0.05) and homoscedasticity of the variances by the Levene test.

Alves et al.
The data were submitted to ANOVA followed by Tukey's means test (P < 0.05) for all continuous variables.The effect of genetic groups at two levels (M NR and M NF1 ) was considered in the linear model of ANOVA.The Kruskal-Wallis non-parametric analysis (P < 0.05) was used for qualitative carcass variables which did not present a normal distribution using the median as a measure of central tendency.
In multivariate analyses, a maximum of 24 characteristics were evaluated simultaneously.Nine groups of traits were used in the Canonical Discriminant Analysis (C DA ) to classify the genetic groups under study: I. body morphology, II.zoometric indices; III.carcass and muscle; IV. carcass morphometry; V. carcass indices; VI. carcass performance; VII.commercial cuts; VIII.cut yield; and IX.mix of variables (all variables simultaneously).The homogeneity of multivariate covariance matrices was assessed using Box's M statistical test (P > 0.05).The discriminant function significance was determined using the Wilks' Lambda statistic (P < 0.05).The main discriminating characteristics between genetic groups was identified by the highest value of the standardized coefficient of the canonical discriminating function (r > 0.50).A factor analysis (F A ) was performed to identify the most relevant characteristics in meat production for the evaluated genetic groups.In addition to reducing the number of variables in factors.The analysis was initially performed for each group of characteristics in a similar way to that described in the C DA .After identifying the main variables within each group of characteristics, an F A was performed to extract the factors.The number of extracted factors followed the Kaiser criterion (eigenvalues > 1; (KASIER, 1960) with orthogonal rotation.The factors were renamed according to the importance of the factor weights of the variables within each factor (> ± 0.50).The model adequacy was assessed using Kaiser-Meyer-Olkin statistical test (KMO = 0.59) and the significance by Bartlett's sphericity test (P < 0.05).
The definition of the potential for each genetic group according to the renamed factors was performed through the hierarchical cluster analysis (HCA).Ward's method and Euclidean distance were used to measure similarity.Next, individual eigenvalues of the M NR and M NF1 lambs were used in the regression method to generate the matrix.From these, the average factor score by genetic group was generated and for each renamed factor.As a complementary analysis, the result of the grouping was plotted using a heatmap generated using the HeatMapper software program (BABICKI et al., 2016).
The Morada Nova beef morphometric index (M NBMI ) was created to facilitate identifying lamb selection to provide greater potential for meat production.The morphometric characteristics and zoometric indices which integrated.The index was selected according to the commonality of each characteristic in the F A .The M NBMI was built from the factor weights of the variables using morphometric measurements, zoometric indices and productive characteristics resulted in the following equation: In which: A I is the anamorphosis index; C H is chest height; R H is rump height; T PRI is the thoracic perimeter relation index; B I is body index; and C W is chest width.An ANOVA between genetic groups was performed followed by a means comparison by the Tukey test (P < 0.001) to validate and apply the M NBMI .

RESULTS
Differences between M NR and M NF1 (P < 0.05) were observed in 12 of the 29 variables for the body morphometric characterization and zoometric indices (Table 1).The zoometric indices (B I , T PRI , A I , B SI , T BI ) classify both genetic groups as longitudinal, compact biotype, prone to meat production ability and respiratory capacity.Differences were observed (P < 0.05) for the anamorphosis index (A I ) and thoracic body index (T BI ).Carcass chest girth, arm length, carcass inner width, and carcass compactness index were heavier (P < 0.05) in the crossbred lambs.
Of the 28 variables studied, including productive and physicochemical characteristics of the carcass, commercial cuts and cut yields (Table 2), only 7 differed between the genetic groups, observing a higher value for M NF1 lambs (P < 0.05).Regarding these variables, the fasting body weight, hot carcass and right half of the carcass weight, rib eye area and rib, loin and brisket weights stood out.Cut yields and carcass physicochemical characteristics were similar (P > 0.05) between genetic groups.Qualitative characteristics (conformation, finishing and evaluation of perirenal fat) did not show an effect on genetic groups (P < 0.05).
The C DA showed that it is possible to differentiate M NR from M N F 1 lambs from the groups of the 9 clusters (Table 3).The zoometric indices were the group of variables which had the highest percentage of correctly classified cases (C CC ) in their group of origin, followed by morphometry.The mix of variables in the simultaneous assessment of all variables belonging to the discriminating groups pointed out that T BI , leg yield, C G and rib weight are the main predictor variables to differentiate purebred lambs from crossbred.The yield of the cuts in isolation did not show any power to differentiate (P = 0.092) the genetic groups.
The eigenvalues and commonality of the variables distributed in the factors are shown in table 4. High commonality values (> 0.90) were obtained in the ranked variables of C WL , T PRI , A I and C EI , while the other variables had values > 0.70.The first four factors explained 85.90% of the total variation in the data, in which the first factor retained 38.5% of the total variance, and constituted the variables with the highest factor load, being renamed morphoeconomic.There was a positive association between C CI , L EA , R H , C H , T D , C W , A I and C EI , but negative - Body index (BI) 94.7 ± 5.0 93.2 ± 2.0 Relative body index (RBI) 110.5 ± 6.0 110.2 ± 2.9 Thoracic perimeter relation index (TPRI) 116.6 ± 5.1 118.1 ± 3.7 Anamorphosis index (AI) 79.2 ± 5.9 b 85.9 ± 4. Ciência Rural, v.53, n.8, 2023.
Alves et al.
with C WL .Higher coefficients in the morphoproductive factor were obtained by C Y , C WL and T PRI , with 18.8% of the explained variance.The factor associated with the commercial characterization was composed of two variables with greater load (Leg yield and B I ).Finally, the equilibrium factor was given by the list of variables which met the analysis assumptions (> 0.5), and that it was not possible to allocate these variables in the first three factors due to their compared low factor load.The heat map (Figure 1) demonstrated the dynamics of the genetic groups based on Table 2 -Mean and standard deviation of productive and physicochemical characteristics of the carcass, commercial cuts and yields of cuts in the Morada Nova red breed lambs (MNR) and F1 crossbred with Morada Nova white breed (MNF1).

DISCUSSION
The morpho-functional and productive description of the M N breed is non-existent, since the morphological evaluation is limited to considerations about breed standard and is only used in promotional events, fairs and exhibitions organized by breeders' associations.This study assesses the productive potential of the M N breed through morphometric, zoometric, productive data and carcass characteristics using a systematic approach with successive multivariate techniques for different objectives.
Our main findings were: (i) zoometric analyzes show the capacity for morpho-productive classification of lambs from the two genetic groups of the M N breed; (ii) the zoometric indices and body morphometry are the main factors responsible for differentiation between the genetic groups evaluated in the study; and (iii) the M NBMI has potential in the area of selection criteria for conservation programs and genetic improvement Morada Nova sheep breed.
The morphological indices used in this study were able to characterize the phenotypic and production potential of M N lambs using the T PRI , A I , B CI "1" and B CI "2" variables, enabling the classification of breeding groups in high thoracic development, ability to produce meat, weight gain, feeding efficiency and breathing capacity, infusing greater breed rusticity and adaptability for both genetic groups (CONTRERAS et al., 2011;RAMOS, I. O. et al., 2019;SILVA-JARQUIN et al., 2019).These characteristics are in agreement with other studies which evaluated adaptability and productive potential of the M N breed, especially the red variety which has greater potential for meat production (LEITE et al., 2020;MELO et al., 2018;REZENDE et al., 2014), in addition to breaking  The superiority observed in some morphometric and productive characteristics in crossbred lambs are justified by the fact that this crossbreed brought together intrinsic characteristics of the white group, meaning that we still observe the result of the heterosis process and complementarity of characteristics between genetic groups, even within the same breed.This mainly because the M NW breed is larger when compared to the M NR (NUNES et al., 2020).Therefore, it is inferred that the crossing between the genetic groups of the M N breed is another alternative to increase the carcass weight resulting in greater cuts, especially noble ones (rib, loin and breast), but with similar cut yields indicating proportionality between carcass and non-carcass components within the two genetic groups.This result may be a peculiar characteristic of using the M N breed in crossbreeding's, since LANDIM et al. (2017) observed similarities between the cut yields in pure M N lambs when compared to crossbred Rabo Largo × M N and Santa Inês × M N lambs.
The developed thoracic body index (T BI ) was fundamental for the survey of the phenotypic diversity among the genetic groups.We believe that the combination of morphometric measures associated with the profile and productive aptitude of the animals, such as B L , W H and T D , used in the index equation was able to efficiently discriminate the genetic groups.Studies indicate the great importance of the T D measurement due to the relationship with digestive capacity and rusticity (SANTOS, L. T. A. Dos, 2019).
The direct relationship between S T and C WL (Table 2) is associated with the carcass quality during the final post-slaughter process, since the cover fat has the main objective to act as a thermal insulator in cooling the carcass, thus providing less loss of weight during the maturation process (LANDIM, et al., 2011;NASCIMENTO, et al., 2018).However, S T was not sufficient to maintain thermal insulation for the evaluated genetic groups, exceeding the value considered adequate (C WL < 7 %; OLIVEIRA et al., 2017).-------------Variables---------------------------------------------------------Factors1 ----------------------------------------- The discrimination in only one canonical discriminating function (Table 3) for the nine selected groups is explained because the genetic groups (white and red) belong to the same breed, which reduced the discriminatory variance shared between the groups.Cut yields do not have the capacity to discriminate genetic groups, which is justified by the similarity between yields (Table 2).The shank yield showed discriminatory power between the genetic groups when all variables were simultaneously analyzed.However, this characteristic acted in a complementary way to the others (T BI , C G and rib weight) to classify 87.0% of the lambs in their group of origin.It is emphasized that adopting the mix of variables is important to identify the main predictor variables for inclusion in genetic breeding programs for M N breed, especially due to the lack of research.
The higher classification rates observed when the zoometric indices and body morphometry were partially analyzed are justified by the higher values in the characteristics related to the thoracic part and the height of the crossbred lambs (Tables 1  and 2), which infer in the efficiency response from the productive point of view, i.e. the ability to gain weight and intake dry matter, which justifies the higher performance of these animals.In contrast, the lowest rates were observed in carcass performance and indexes, as the effect of crossbreeding between genetic groups did not influence most carcass variables (MELO et al., 2018;RAMOS, I. O. et al., 2019).
In this study, the potential for meat production was assessed by factor analysis, in which the characteristics linearly associated with each other were distributed through their respective loads, making it possible to compose factors with biological and economic interpretation.The first factor grouped a larger number of variables including those which indirectly affect the final carcass characteristics; and therefore, acted in the economic scope of meat production.This factor also pointed out that C WL is the single factor which most compromises the economic index, since losses due to cooling interfere with the carcass weight and quality, and consequently reduce its price.For LANDIM et al. (2017, 2021), an alternative to increase C WL is the use of the Rabo Largo breed in terminal crossbreeding.
The C EI inferred greater explanatory power due to the four factors extracted, in addition to having a high correlation with the A I , which is considered an important indicator of meat production (SABBIONI et al., 2016).Therefore, if there is selection in the M N breed for this morphological index, there will indirectly be a positive influence on the economic aspect.We highlight the associations between morphometric measures and important traits in meat production (e.g., chest height and rib eye area, C CI The second factor extracted in the factor analysis, is associated with characteristics which exert great influence on the productive potential of the M N breed.It is possible to predetermine the digestive capacity and weight gain of a given animal using T PRI (NUNES et al., 2020), while C Y can be used in sheep farming in response to the relative percentage of meat to be marketed, as lambs generally have high yields and small variations between biotypes (OLIVEIRA, et al., 2018).
The factor associated with commercial characterization, which in turn is directly related to the animal's production capacity, and consequently greater body and carcass weight, has a direct influence with Leg Yield, as this variable has the greatest quantitative representation of a sheep carcass (OLIVEIRA, F. G. et al., 2018;TADEU et al., 2013).The chest height indicates the stature of the animal, and it is recommended to raise small sheep for the Caatinga biome since the availability of food during the dry period of the year is mostly located in herbaceous extract (NUNES et al., 2020).In addition, animals with a compact profile and small to medium body structure should be chosen if the breeder intends to raise animals for meat production with a high capacity for weight gain (RAMOS, I. O. et al., 2019).
The grouping plotted on the heat map clarified the specificities for meat production of the genetic groups.M NF1 lambs presented superiority in the productive, commercial and economic aspects, while the M NR lambs were balanced.Moreover, ISSAKOWICZ et al. (2018) report that the lower meat production potential for the M NR breed when compared to other native sheep breeds is related to the small size of this breed group; however, morphoproductive characterizations are useful approaches to circumvent this limitation, as they identify the main characteristics related to the productive potential and use them as a selection criterion.The cluster formed by the morpho-economic and morpho-commercial factors is justified by their direct relationship between factors, while the balance was related to the morpho-productive factor, especially with emphasis on the crossbred lambs due to their greater production when compared to the purebred lambs.
The M NBMI suggests that sheep obtained by crossbreeding the white and red genetic groups of the M N breed have a greater potential for meat production when compared with M NR lambs, demonstrating the importance of the white genetic group participating in terminal crossbreeding.
Finally, this research identified predictive morphological parameters for meat production with the creation of an aggregate index obtained from the variables with greater participation in the multivariate analysis.This index presents itself as an early and practical selection criterion for meat production in M N lambs, and can be used in breeding programs for sheep and by farmers, since biometrics is a simple and easy tool to perform.It is also expected to contribute to the recovery process of the M N white breed variety, as its use has been shown to be favorable in sheep meat production.

CONCLUSION
M NR and M NF1 lambs present high thoracic development, compact biotype and aptitude for meat production.Traits such as T BI , Leg yield., C G and rib weight were generally the most important for differentiating the genetic groups of the M N breed.The chest height, rump height and anamorphosis index showed to be important variables in the choice of M N lambs with meat production potential.The M NF1 lambs were shown to have greater potential for meat production than M NR , being recommended as a sustainable strategy in semi-arid regions.Additionally, this crossing would facilitate the conservation of the white variety of the M N breed, in imminent risk of extinction.It is recommended that M NBMI be used as a tool for morpho-productive selection criteria in M N breeding programs; however, further studies are needed in larger populations of this breed and in other small native breeds.

3
Statistic test: Canonical functions (FC1) with P < 0.05 of Wilks' Lambda were considered significant.4 Main traits of the groups: CH = chest height; CG = chest girth; CW = chest width; RH = rump height; BI = body index; TPRI = Thoracic perimeter relation index; AI = anamorphosis index; TBI = thoracic body index; LEA = loin eye area; PF = perirenal fat; CGC = carcass chest girth; CCI = carcass compactness index; HCW = hot carcass weight; Leg Y. = leg yield.Ciência Rural, v.53, n.8, 2023.Alves et al. paradigms about the low adaptability of white M N to the semi-arid environment.The scarcity of data associated with morphometry and productive indicators in sheep raised in the Northeast region of Brazil makes it impossible to compare results with other breeds.Other studies carried out in a semi-arid region of Africa with Uda sheep classify this breed as short bodied, large proportionality which correlate with good health, breviline, poor thoracic development which is an indication of poor traction (DAUDA, 2018).

Figure 1 -
Figure 1 -Heatmap of the main components for productive carcass characteristics, morphometry and zoomometric indexes in Morada Nova breed red lambs (MNR) and crossbred with the white (MNF1).Positive Z-score values show a positive association between the genetic groups (lines) and factors.

Figure 2 -
Figure 2 -Boxplot of the Morada Nova beef morphometric index (MNBMI).Morada Nova breed red (MNR) and crossbred with the white (MNF1).Means followed by different letters are statistically different by the Tukey test (P < 0.001).

Table 1 -
Mean and standard deviation of measurements and morphometric indices in vivo and in the carcass of the Morada Nova red breed (MNR) lambs and F1 crossbred with Morada Nova white breed (MNF1).

Table 3 -
Canonical discriminant analysis for carcass characteristics, morphometry and zoometric indices in Morada Nova red breed lambs (MNR) and F1 crossbred with Morada Nova white breed (MNF1).
1 Total percentage of cases correctly classified: CCC = cases correctly classified. 2 Percentage of cases correctly classified by genetic group.

Table 4 -
Factor analysis for carcass productive characteristics, morphometry and zoometric indices in Morada Nova lambs.