Inference of extinction

Solow (Reference Solow1993) proposed one of the first statistical methods for the inference of extinction. Specifically the method tests for the likelihood of species persistence (p) in relation to the number of times a species has been recorded (n) within the whole observation period (T), where t _n is the time of the last collection within the observation period:

(1)$${\,p = {\left( {\displaystyle{{t_n} \over T}} \right)}^n}$$

In line with the discrete nature of most collection records (Solow, Reference Solow2005; Rivadeneira et al., Reference Rivadeneira, Hunt and Roy2009) and the method discussed below (McCarthy, Reference McCarthy1998), we treat time as discrete, with multiple collections allowed within each time unit. A discrete-time form of Solow equation was established by Burgman et al. (Reference Burgman, Grimson and Ferson1995):

(2)$${\,p = {\left( {\displaystyle{{C_e} \over {C_T}}} \right)}^n}$$

where the time period (0,T) is partitioned into C _T equally-sized time units and C _e is the number of time intervals between the start of the observation period and the last collection (Burgman et al., Reference Burgman, Grimson and Ferson1995, Reference Burgman, Maslin, Andrewartha, Keatley, Boek, McCarthy, Scott and Burgman2000).

This gives rise to the question of when is the start of the observation period (t ₀)? Often the first collection of the species is used as t ₀, and therefore n reduces by 1. However, other events may be used to denote the start of the collection period, such as the first year of an annual survey or the year the first specimen was collected (Roberts & Solow, Reference Roberts and Solow2003). Accordingly, species known from a single specimen require some other event, rather than their first collection, to denote the start of the observation period. Here we take the first year with collections, 1830, as the start of the collection period. An alternative option to selecting a dataset-specific starting date would be to use a global standard starting date; e.g. 1753 or 1758 as the start of the Linnaean binomial nomenclature.

In case of species known from a single collection n = 1 and therefore p reduces to t _n/T. In other words, for an extinction to be inferred at some significance level (i.e. P < 0.05), the time since the specimen was observed has to be > 19 times greater than the time prior to the specimen being collected. This is not dissimilar to the non-parametric method described by Solow & Roberts (Reference Solow and Roberts2003).

McCarthy (Reference McCarthy1998) modified equation (1) to take into account annual collection effort (e _i), which we consider here to be the annual number of collected specimens of all species. The so-called partial Solow equation is based on the relationship between the collection effort prior to the last collection and the total collection effort (McCarthy, Reference McCarthy1998):

(3)$${\,p = {\left( {\sum\limits_{i = {\rm 0}}^{t_n} {e_i} /\sum\limits_{i = {\rm 0}}^T {e_i}} \right)}^n}$$

As in Solow (Reference Solow1993), when n = 1 McCarthy's (Reference McCarthy1998) equation becomes simply the proportion of the effort prior to the specimen being collected to the total effort over the whole collection period. As a result, extinction may be inferred once p decreases below a certain statistical threshold (e.g. P < 0.05). In cases where the threshold is set at P < 0.05, the amount of effort that was expended (in terms of the number of specimens collected) after the specimen was collected has to be > 19 times greater than the effort expended before the collection.

This method assumes that there is no systematic trend in the likelihood of detection over time, caused for example by a gradually declining population prior to extinction (Roberts et al., Reference Roberts, Elphick and Reed2010). We address the effect of a declining population abundance and detectability prior to extinction in the sensitivity analysis, described below.

Specimen data

Using the Orchids of Madagascar Checklist (Hermans et al., Reference Hermans, Hermans, Du Puy, Cribb and Bosser2007) as a baseline taxonomy, we used data compiled from 21 herbaria, using all available herbarium specimens for the region (Rivers et al., Reference Rivers, Taylor, Brummitt, Meagher, Roberts and Lughadha2011), including non-endemics, totalling 4,342 specimens. The dataset comprises species that were considered to represent distinct species based on current knowledge (Hermans et al., Reference Hermans, Hermans, Du Puy, Cribb and Bosser2007). As the analysis was made at the species level, specimens recorded at the subspecies and lower taxonomic levels were categorized as species for this purpose. We excluded all records identified as erroneous (i.e. erroneous observation year or collection locations outside Madagascar, n = 8), specimens identified as hybrids (n = 4) and duplicates that represented the same species collected at the same site on the same date (n = 22). In addition, three specimens collected before 1830 (1682–1695) were excluded as they were temporally remote from the rest of the collections. A further 63 specimens collected after 2000 were also removed, to avoid the bias of the time taken for specimens to be incorporated into collections and the period taken to compile the dataset. The first collection (a specimen from 1830) was also excluded and used as the beginning of the collection period. The final dataset comprised 4,241 specimens, representing 762 species from 57 genera, collected over a 170-year period (1831–2000).

Estimating collection effort over time using museum specimens

One of the assumptions when using specimen collections as a measure of effort is that the species composition should remain constant over the collection period (i.e. there should be no significant changes in the number of species or their relative abundances over time). To account for a lack of information on the status, decline and potential extinction of species in the dataset, we used three subsets of collections as measures of collection effort (Fig. 1b): (1) all collections of all species (n = 4,241), (2) all collections of only the 10% most collected species, assuming that such species were less likely to be in decline or extinct and also better represent general effort (n = 2,018), and (3) all collections of species identified by the optimal linear estimator (OLE) method for the inference of extinction (Roberts & Solow, Reference Roberts and Solow2003; Solow, Reference Solow2005) as being extant in 2000 (n = 2,828). Each species was assessed separately, and the standard significance threshold was used to infer extinction (P < 0.05). The third approach was applied only to species with ≥ 5 collections (Solow, Reference Solow2005), with all other species (i.e. with < 5 collections) excluded from the dataset (513 species, 963 records). This method was applied using no more than the 10 most recent collections for each species (Rivadeneira et al., Reference Rivadeneira, Hunt and Roy2009), which excluded a further 37 species (450 records) from the dataset.

Fig. 1 Number of orchid collections in Madagascar per year during 1830–2000 as (a) collections of orchid species known from a single specimen (n = 236), and (b) as collections of all species, used as a measure of collection effort, with three subsets: all collections of all species (n = 4,241), all collections of only the 10% most collected species (n = 2,018), and all collections of species identified as being extant in 2000, based on the OLE method (n = 2,828; see text for additional details).

Using the dataset of Malagasy orchid specimens as a measure of effort, we assessed the extinction likelihood of the 236 species known from a single specimen (Supplementary Material 1). Extinction was inferred by the McCarthy (Reference McCarthy1998) method (equation 3), with α = 0.05. For species inferred by at least one of the three measures of effort as likely to be extant in 2000, we also tested whether the critical threshold (P < 0.05) would be reached by 2018 based on the expected annual collection effort (i.e. the annual number of collected specimens of all species) during 2001–2018. Collection effort for this period was estimated by using the effort observed over the last decade of the collection period (1991–2000), and the lower (mean – SD), mean and upper (mean + SD) collection effort estimate. A t test of the slope of the regression line over 1991–2000 indicated a lack of any trend over this period (P > 0.05); i.e. collection effort did not significantly differ from the previous decade. Although the method assumes uniform collection effort over the studied area, we did not conduct spatial analysis of effort. Supplementary Material 2 provides the R 3.4.3 (R Core Team, 2017) script for testing extinction of species known from a single specimen and for estimating the collection effort required to confirm extinction.

Sensitivity analysis

To test and compare the performance of the applied method (equation 3) under different extinction and sampling scenarios, we applied the method described by Rivadeneira et al. (Reference Rivadeneira, Hunt and Roy2009). A series of artificial collection records were generated and simulated in R. A total of 54 scenarios were simulated that differed based on the collection effort intensity and trend, collection period duration before the time of extinction, and the type of extinction. Simulated time of extinction was set to occur either 20, 50 or 100 years after the beginning of the collection period, and the collection effort was allowed to continue for up to 10,000 years, to provide sufficient amount of post-extinction effort for extinction to be inferred. Scenarios were developed with two processes of extinction (instant vs gradual), three levels of collection effort (10, 20 or 40 specimens/year in the initial year) and three collection effort trends (stable, increasing or decreasing effort over time). In scenarios with instant extinction, species collection probability remained the same over time until the time of extinction, whereas in gradual extinction scenarios it declined linearly over time. Stable collection effort was represented by a constant number of specimens collected over time, and the increasing and decreasing collection effort trends were represented by 1% annual rate of change in the collected number of specimens. Decreasing collection effort was allowed to drop to the minimum value of one collected specimen per year, after which it remained constant in all subsequent years. Target species collection probability was approximated in such a way as to obtain on average only a single specimen over the whole collection period within each simulation, and the simulations were repeated until 10,000 simulations with a single species collection were obtained for each scenario.

The upper bounds of a 95% confidence interval (CI) of the method were evaluated based on their statistical coverage (i.e. on the appropriateness of the 95% confidence intervals). An accurate and reliable method should have exactly 95% of simulated extinctions falling within the estimated CI (Rivadeneira et al., Reference Rivadeneira, Hunt and Roy2009). Lower coverage indicates tendency of the method to underestimate the true time of extinction (i.e. Type I error), and coverage above 95% indicates overly conservative predictions and the tendency to overestimate time of extinction (Type II error). For more information on this approach, see Rivadeneira et al. (Reference Rivadeneira, Hunt and Roy2009). The difference between the time of the last collection and the estimated CI was also assessed for each scenario.